A. A. Albert :
A determination of all associative algebras in two, three and four units over a nonmodular field \( \frak{F} \) .
M.S. Thesis ,
University of Chicago ,
1927 .
phdthesis
BibTeX
@phdthesis {key87235121,
AUTHOR = {A. A. Albert},
TITLE = {A determination of all associative algebras
in two, three and four units over a
nonmodular field \$\frak{F}\$},
TYPE = {M.S. Thesis},
SCHOOL = {University of Chicago},
YEAR = {1927},
PAGES = {111},
}
A. A. Albert :
Algebras and their radicals and division algebras .
Ph.D. thesis ,
University of Chicago ,
1928 .
Advised by L. E. Dickson .
MR
2611246
phdthesis
People
BibTeX
@phdthesis {key2611246m,
AUTHOR = {Albert, Abraham Adrian},
TITLE = {Algebras and their radicals and division
algebras},
SCHOOL = {University of Chicago},
YEAR = {1928},
URL = {http://www.getcited.org/pub/102113022},
NOTE = {Advised by L. E. Dickson.
MR:2611246.},
}
A. A. Albert :
“Normal division algebras satisfying mild assumptions ,”
Proc. Nat. Acad. Sci. U.S.A.
14 : 12
(December 1928 ),
pp. 904–906 .
JFM
54.0161.04
article
Abstract
BibTeX
Let \( D \) be a normal division algebra in \( n^2 \) units over an infinite field \( F \) . Every element of \( D \) satisfies some equation of degree \( n \) , with leading coefficient unity and further coefficients in \( F \) . There exists an infinity of elements of \( D \) satisfying an equation of this kind, irreducible in \( F \) .
@article {key54.0161.04j,
AUTHOR = {Albert, A. A.},
TITLE = {Normal division algebras satisfying
mild assumptions},
JOURNAL = {Proc. Nat. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {14},
NUMBER = {12},
MONTH = {December},
YEAR = {1928},
PAGES = {904--906},
DOI = {10.1073/pnas.14.12.904},
NOTE = {JFM:54.0161.04.},
ISSN = {0027-8424},
}
A. A. Albert :
“The group of the rank equation of any normal division algebra ,”
Proc. Natl. Acad. Sci. USA
14 : 12
(December 1928 ),
pp. 906–907 .
JFM
54.0161.05
article
BibTeX
@article {key54.0161.05j,
AUTHOR = {Albert, A. A.},
TITLE = {The group of the rank equation of any
normal division algebra},
JOURNAL = {Proc. Natl. Acad. Sci. USA},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {14},
NUMBER = {12},
MONTH = {December},
YEAR = {1928},
PAGES = {906--907},
DOI = {10.1073/pnas.14.12.906},
NOTE = {JFM:54.0161.05.},
ISSN = {0027-8424},
}
A. A. Albert :
“A determination of all normal division algebras in sixteen units ,”
Bull. Am. Math. Soc.
34 : 4
(1928 ),
pp. 410–411 .
Abstract only; paper in Trans. Am. Math. Soc. 31 :2 (1929) .
JFM
54.0166.16
article
BibTeX
@article {key54.0166.16j,
AUTHOR = {Albert, A. A.},
TITLE = {A determination of all normal division
algebras in sixteen units},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {34},
NUMBER = {4},
YEAR = {1928},
PAGES = {410--411},
DOI = {10.1090/S0002-9904-1928-04552-4},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{31}:2 (1929).
JFM:54.0166.16.},
ISSN = {0002-9904},
}
A. A. Albert :
“On the structure of normal division algebras ,”
Ann. Math. (2)
30 : 1–4
(1928–1929 ),
pp. 322–338 .
An abstract was published in Bull. Am. Math. Soc. 35 :2 (1929) .
MR
1502886
JFM
55.0682.01
article
Abstract
BibTeX
The chief outstanding problem in the theory of linear associative algebras is the determination of all normal division algebras. In the present paper we shall add to the present meager knowledge of the structure of such algebras by proving certain basic theorems on the structure of algebras satisfying mild postulates. We shall also, in the exposition of this theory, prove certain theorems tactily assumed by writers in the theory of division algebras, and define new terms to be used here and in subsequent papers.
We shall consider normal linear associative division algebras over a non-modular field \( F \) and shall speak of them, simply, as normal division algebras. The general non-modular reference field \( F \) shall be understood unless the contrary is explicitly stated.
@article {key1502886m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On the structure of normal division
algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {30},
NUMBER = {1--4},
YEAR = {1928--1929},
PAGES = {322--338},
DOI = {10.2307/1968284},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{35}:2 (1929).
MR:1502886. JFM:55.0682.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“Normal division algebras in \( 4p^2 \) units, \( p \) an odd prime ,”
Ann. Math. (2)
30 : 1–4
(1928–1929 ),
pp. 583–590 .
MR
1502907
JFM
55.0683.01
article
Abstract
BibTeX
We shall consider normal associative division algebras in \( 4p^2 \) units, over any non-modular field \( F \) , satisfying special assumptions. We shall utilize the definitions and theorems of a previous paper [1929], referring to the theorems by numbers 1 to 29 and shall number the theorems of this paper beginning with 30.
In the paper above referred to we have defined “known algebras” and “the type of an irreducible equation, of an element of a normal division algebra, and of a normal division algebra”.
L. E. Dickson [1926] has found the structure of all normal division algebras in \( n^2 \) units over \( F \) , of type \( R_n \) , that is, normal division algebras containing an element \( x \) whose minimum equation is of degree \( n \) and has the property that all of its scalar roots are rational functions, with coefficients in \( F \) , of one of them. He has also determined and constructed the algebras when the minimum equation of this \( x \) has a solvable group. These algebras are easily seen to be known algebras under our definition and the resulting criterion shall be utilized here.
@article {key1502907m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Normal division algebras in \$4p^2\$ units,
\$p\$ an odd prime},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {30},
NUMBER = {1--4},
YEAR = {1928--1929},
PAGES = {583--590},
DOI = {10.2307/1968306},
NOTE = {MR:1502907. JFM:55.0683.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“The structure of any algebra which is a direct product of rational generalized quaternion division algebras ,”
Ann. Math. (2)
30 : 1–4
(1928–1929 ),
pp. 621–625 .
MR
1502911
JFM
55.0683.02
article
Abstract
BibTeX
Before Cecioni’s discovery of normal division algebras in sixteen units which are non-cyclic in form attempts were made to construct such algebras by the construction of division algebras which were the direct products of two rational generalized quaternion algebras. Such attempts are here shown to have been futile as no such direct product is ever a division algebra. We also, in the nature of a corollary, give the structure of any algebra which is the direct product of \( n \) generalized quaternion division algebras.
@article {key1502911m,
AUTHOR = {Albert, A. Adrian},
TITLE = {The structure of any algebra which is
a direct product of rational generalized
quaternion division algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {30},
NUMBER = {1--4},
YEAR = {1928--1929},
PAGES = {621--625},
DOI = {10.2307/1968310},
NOTE = {MR:1502911. JFM:55.0683.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“On the rank equation of any normal division algebra ,”
Bull. Am. Math. Soc.
35 : 3
(1929 ),
pp. 335–338 .
MR
1561740
JFM
55.0090.03
article
Abstract
BibTeX
The different types of normal division algebras which have been discovered up to the present depend upon equations with different groups. It has been thought that, as the rank equation of an algebra is invariant under a change of basal units, the groups of the rank equations of these various types of algebras might serve to show their non-equivalence. This notion is shown to be false here, as the group of the rank equation of any normal division algebra is the symmetric group. In proving this theorem a new theorem in the Hubert theory of an irreducible polynomial whose coefficients are rational functions, with coefficients in any infinite field \( K \) , of several parameters is developed.
@article {key1561740m,
AUTHOR = {Albert, A. A.},
TITLE = {On the rank equation of any normal division
algebra},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {35},
NUMBER = {3},
YEAR = {1929},
PAGES = {335--338},
DOI = {10.1090/S0002-9904-1929-04744-X},
NOTE = {MR:1561740. JFM:55.0090.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“A determination of all normal division algebras in sixteen units ,”
Trans. Am. Math. Soc.
31 : 2
(1929 ),
pp. 253–260 .
An abstract was published in Bull. Am. Math. Soc. 34 :4 (1928) .
MR
1501481
JFM
55.0090.04
article
Abstract
BibTeX
The chief outstanding problem in the theory of linear associative algebras over an infinite field \( F \) is the determination of all division algebras. This problem is equivalent to that of the determination of all normal division algebras, or algebras \( A \) in which the only elements of \( A \) commutative with every element of \( A \) are the quantities of its reference field \( F \) .
The order of a normal division algebra is the square of an integer. All normal division algebras in \( 1^2 \) , \( 2^2 \) [Dickson 1927, p. 46], and \( 3^2 \) [Wedderburn 1921, p. 132] units have been determined. In this paper all normal division algebras in \( 4^2 \) units, the next case, are determined and shown to be the algebras of Cecioni [1923].
@article {key1501481m,
AUTHOR = {Albert, A. Adrian},
TITLE = {A determination of all normal division
algebras in sixteen units},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {31},
NUMBER = {2},
YEAR = {1929},
PAGES = {253--260},
DOI = {10.2307/1989383},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{34}:4 (1928).
MR:1501481. JFM:55.0090.04.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“The rank function of any simple algebra ,”
Proc. Natl. Acad. Sci. U.S.A.
15 : 4
(April 1929 ),
pp. 372–376 .
An abstract was published in Bull. Am. Math. Soc. 35 :4 (1929) .
JFM
55.0683.03
article
Abstract
BibTeX
No special properties of the rank function of a simple algebra have been given in the literature except for the limiting cases of a total matric algebra and a normal division algebra. We consider here the general simple algebra, first represented as a normal algebra over its central field, the field of all of its elemetns commutative with every one of its elements, and then as a simple algebra over \( F \) , and obtain the rank and irreducibility of the rank function.
@article {key55.0683.03j,
AUTHOR = {Albert, A. A.},
TITLE = {The rank function of any simple algebra},
JOURNAL = {Proc. Natl. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {15},
NUMBER = {4},
MONTH = {April},
YEAR = {1929},
PAGES = {372--376},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{35}:4 (1929).
JFM:55.0683.03.},
ISSN = {0027-8424},
}
A. A. Albert :
“On the structure of normal division algebras ,”
Bull. Am. Math. Soc.
35 : 2
(1929 ),
pp. 182–183 .
Abstract only; paper in Ann. Math. 30 :1–4 (1928–1929) .
JFM
55.0092.03
article
BibTeX
@article {key55.0092.03j,
AUTHOR = {Albert, A. A.},
TITLE = {On the structure of normal division
algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {35},
NUMBER = {2},
YEAR = {1929},
PAGES = {182--183},
DOI = {10.1090/S0002-9904-1929-04691-3},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{30}:1--4 (1928--1929).
JFM:55.0092.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“The rank function of any simple algebra ,”
Bull. Am. Math. Soc.
35 : 4
(1929 ),
pp. 441 .
Abstract only; paper in Proc. Natl. Acad. Sci. U.S.A. 15 :4 (1929) .
JFM
55.0092.05
article
BibTeX
@article {key55.0092.05j,
AUTHOR = {Albert, A. A.},
TITLE = {The rank function of any simple algebra},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {35},
NUMBER = {4},
YEAR = {1929},
PAGES = {441},
DOI = {10.1090/S0002-9904-1929-04740-2},
NOTE = {Abstract only; paper in \textit{Proc.
Natl. Acad. Sci. U.S.A.} \textbf{15}:4
(1929). JFM:55.0092.05.},
ISSN = {0002-9904},
}
A. A. Albert :
“A necessary and sufficient condition for the non-equivalence of any two rational generalized quaternion division algebras ,”
Bull. Am. Math. Soc.
36 : 8
(1930 ),
pp. 535–540 .
An abstract was published in Bull. Am. Math. Soc. 36 :3 (1930) .
MR
1561990
JFM
56.0145.03
article
Abstract
BibTeX
Two algebras \( \mathfrak{A} \) and \( \mathfrak{B} \) over the same field \( F \) are called equivalent (or simply isomorphic ) if it is possible to establish between their quantities a (1-1) correspondence such that if any quantities \( x \) and \( y \) of \( \mathfrak{A} \) correspond to \( X \) and \( Y \) of \( \mathfrak{B} \) , then \( x+y \) , \( xy \) and \( \alpha x \) correspond to \( X + Y \) , \( XY \) , \( \alpha X \) respectively for every \( \alpha \) of \( F \) . We shall consider two generalized quaternion division algebras \( \mathfrak{A} \) and \( \mathfrak{B} \) over the field of all rational numbers, \( R \) .
@article {key1561990m,
AUTHOR = {Albert, A. A.},
TITLE = {A necessary and sufficient condition
for the non-equivalence of any two rational
generalized quaternion division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {8},
YEAR = {1930},
PAGES = {535--540},
DOI = {10.1090/S0002-9904-1930-04991-5},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{36}:3 (1930).
MR:1561990. JFM:56.0145.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“A construction of all non-commutative rational division algebras of order eight ,”
Bull. Am. Math. Soc.
36
(1930 ),
pp. 214 .
Article only; paper in Ann. Math. 31 :4 (1930) .
JFM
56.0152.24
article
Abstract
BibTeX
By rational algebras is meant algebras over the field \( R \) of all rational numbers. All rational generalized quaternion division algebras and all rational cyclic division algebras of order sixteen have been constructed [Albert 1930]. Also a type of cyclic division algebra of order nine has been given [Dickson 1923, pp. 68–71]. In the present paper the problem of the construction of all non-commutative rational division algebras of order eight is considered and solved, necessary and sufficient conditions being given that the algebras constructed be division algebras. These conditions are explicit diophantine conditions on the constants of the general algebra in one of two canonical forms.
@article {key56.0152.24j,
AUTHOR = {Albert, A. A.},
TITLE = {A construction of all non-commutative
rational division algebras of order
eight},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
YEAR = {1930},
PAGES = {214},
DOI = {10.1090/S0002-9904-1930-04929-0},
NOTE = {Article only; paper in \textit{Ann.
Math.} \textbf{31}:4 (1930). JFM:56.0152.24.},
ISSN = {0002-9904},
}
A. A. Albert :
“New results in the theory of normal division algebras ,”
Trans. Am. Math. Soc.
32 : 2
(1930 ),
pp. 171–195 .
An abstract was published in Bull. Am. Math. Soc. 36 :3 (1930) .
MR
1501532
JFM
56.0146.01
article
Abstract
BibTeX
The author shows that in every normal division algebra \( A \) in sixteen units over \( R \) , the field of all rational numbers, there are eight integer parameters \( \rho, \sigma, \gamma_1,\dots,\gamma_6 \) , where neither \( \rho \) , \( \sigma \) , nor \( \rho\sigma \) is a rational square. Algebra \( A \) is associative if and only if
\[ (\gamma_5^2 - \gamma_6^2\sigma\rho) = (\gamma_1^2-\gamma_2^2\rho)(\gamma_3^2 - \gamma_4^2\sigma) \]
and is a division algebra if and only if the ternary quadratic form
\[ \lambda_1^2 - \sigma\lambda_2^2 - (\gamma_1^2 - \gamma_2^2\rho)\lambda_3^2 ,\]
in the integer variables \( \lambda_1 \) , \( \lambda_2 \) , \( \lambda_3 \) is not a null form. As all ternary quadratic null forms are known, this amounts to a construction of all normal division algebras of order sixteen over \( R \) in terms of the solutions of a single diophantine equation which satisfy a single quadratic residue condition. Necessary and sufficient algebraic conditions that \( A \) be a cyclic algebra are given, and it is shown that all of the algebras constructed by Cecioni are cyclic. An algebra \( A \) is shown to be non-cyclic if and only if two quartic forms with coefficients polynomials in \( \rho \) , \( \sigma \) , \( \gamma_1,\dots,\gamma_6 \) are non-null forms.
@article {key1501532m,
AUTHOR = {Albert, A. Adrian},
TITLE = {New results in the theory of normal
division algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {32},
NUMBER = {2},
YEAR = {1930},
PAGES = {171--195},
DOI = {10.2307/1989489},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{36}:3 (1930).
MR:1501532. JFM:56.0146.01.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“A determination of the integers of all cubic fields ,”
Ann. Math. (2)
31 : 4
(October 1930 ),
pp. 550–566 .
An abstract was published in Bull. Am. Math. Soc. 36 :3 (1930) .
MR
1502961
JFM
56.0870.01
article
Abstract
BibTeX
Elementary explicit formulae for integral bases of fields \( R(\theta) \) , where \( \theta \) is a root of an equation \( f(x)=0 \) of degree \( n \) with coefficients in the field \( R \) of all rational numbers and irreducible in \( R \) , have been given for only the case \( n = 2 \) and various special types of fields. In the present paper the author considers the case \( n = 3 \) and completely determines integral bases of all cubic fields in terms of elementary number-theoretic functions of the coefficients of the general cubic in its reduced form.
@article {key1502961m,
AUTHOR = {Albert, A. Adrian},
TITLE = {A determination of the integers of all
cubic fields},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {31},
NUMBER = {4},
MONTH = {October},
YEAR = {1930},
PAGES = {550--566},
DOI = {10.2307/1968153},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{36}:3 (1930).
MR:1502961. JFM:56.0870.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“A note on an important theorem on normal division algebras ,”
Bull. Am. Math. Soc.
36 : 10
(1930 ),
pp. 649–650 .
MR
1562029
JFM
56.0145.04
article
Abstract
BibTeX
@article {key1562029m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on an important theorem on normal
division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {10},
YEAR = {1930},
PAGES = {649--650},
DOI = {10.1090/S0002-9904-1930-05021-1},
NOTE = {MR:1562029. JFM:56.0145.04.},
ISSN = {0002-9904},
}
A. A. Albert :
“Determination of all normal division algebras in thirty-six units of type \( R_2 \) ,”
Am. J. Math.
52 : 2
(1930 ),
pp. 283–292 .
MR
1507918
JFM
56.0145.06
article
Abstract
BibTeX
An element \( x \) of a normal division algebra \( A \) in \( n^2 \) units over a non-modular field \( F \) is said to have grade \( r \) if its minimum equation has degree \( r \) . If there exist \( k \) distinct elements \( x \) , \( \theta_1(x),\dots,\theta_{k-1}(x) \) which are polynomials in \( x \) and satisfy its minimum equation then \( x \) is said to have type \( R_k \) . Algebra \( A \) in \( n^2 \) units has type \( R_k \) if it contains an element of grade \( n \) and type \( R_k \) .
In all of the papers [Wedderburn 1921; Albert 1929a] on the determination of normal division algebras the algebras were first shown to be of type \( R_2 \) and then proved to be known algebras. For algebras \( A \) in \( n^2 \) units, \( n \) a prime, the assumption that \( A \) has type \( R_2 \) implies, by an almost trivial argument, that \( A \) has type \( R_n \) and is a cyclic algebra. But when \( n \) is composite the problem of showing \( A \) to be known is difficult even under the assumption that \( A \) has type \( R_2 \) . We consider here the case \( n=6 \) and show that all normal division algebras in thirty-six units of type \( R_2 \) are of type \( R_3 \) and are known in the broad sense recently defined [Albert 1929b]. A necessary and sufficient condition that the known algebras be of type \( R_6 \) and hence of the kind constructed by L. E. Dickson is also given.
@article {key1507918m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Determination of all normal division
algebras in thirty-six units of type
\$R_2\$},
JOURNAL = {Am. J. Math.},
FJOURNAL = {American Journal of Mathematics},
VOLUME = {52},
NUMBER = {2},
YEAR = {1930},
PAGES = {283--292},
DOI = {10.2307/2370683},
NOTE = {MR:1507918. JFM:56.0145.06.},
ISSN = {0002-9327},
CODEN = {AJMAAN},
}
A. A. Albert :
“The non-existence of pure Riemann matrices with normal multiplication algebras of order sixteen ,”
Ann. Math. (2)
31 : 3
(1930 ),
pp. 375–380 .
An abstract was published in Bull. Am. Math. Soc. 36 :3 (1930) .
MR
1502951
JFM
56.0869.02
article
Abstract
BibTeX
@article {key1502951m,
AUTHOR = {Albert, A. Adrian},
TITLE = {The non-existence of pure {R}iemann
matrices with normal multiplication
algebras of order sixteen},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {31},
NUMBER = {3},
YEAR = {1930},
PAGES = {375--380},
DOI = {10.2307/1968233},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{36}:3 (1930).
MR:1502951. JFM:56.0869.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“The integers of normal quartic fields ,”
Ann. Math. (2)
31 : 3
(July 1930 ),
pp. 381–418 .
MR
1502952
JFM
56.0870.02
article
Abstract
BibTeX
The integral bases of all relative quadratic fields \( K(\sqrt{\mu}) \) where \( \mu \) is in \( K = R(\sqrt{m}) \) have been found [Sommer 1907] by the theory of ideals. But these bases are given in terms of factorization of two and \( \mu \) into prime ideals, the solution of a quadratic congruence modulo ideals and further complicated processes. The formulae are inexplicit and are almost useless for application to special cases, a situation not at all like that of the case of quadratic fields.
We consider here all normal quartic fields \( R(i) \) where \( R \) is the field of all rational numbers and \( i \) is a root of a quartic equation with rational coefficients and either the cyclic group or the “Vierergruppe” with respect to \( R \) . All such fields are relative quadratic fields. But here, utilizing the known canonical forms of such quartics and strictly elementary methods, we obtain explicit formulae for the bases of the integers of any normal quartic field in terms of the coefficients of the corresponding quartic equation.
@article {key1502952m,
AUTHOR = {Albert, A. Adrian},
TITLE = {The integers of normal quartic fields},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {31},
NUMBER = {3},
MONTH = {July},
YEAR = {1930},
PAGES = {381--418},
DOI = {10.2307/1968234},
NOTE = {MR:1502952. JFM:56.0870.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“On the structure of pure Riemann matrices with non-commutative multiplication algebras ,”
Proc. Natl. Acad. Sci. U.S.A.
16 : 4
(April 1930 ),
pp. 308–312 .
JFM
56.0329.08
article
Abstract
BibTeX
The chief outstanding problem in the theory of Riemann matrices is the determination of all pure Riemann matrices. It is the purpose of this paper to give certain basic theorems on the structure of such matrices, and, in particular, the case where the multiplication algebra is a known normal division algebra.
@article {key56.0329.08j,
AUTHOR = {Albert, A. Adrian},
TITLE = {On the structure of pure Riemann matrices
with non-commutative multiplication
algebras},
JOURNAL = {Proc. Natl. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {16},
NUMBER = {4},
MONTH = {April},
YEAR = {1930},
PAGES = {308--312},
DOI = {10.1073/pnas.16.4.308},
NOTE = {JFM:56.0329.08.},
ISSN = {0027-8424},
}
A. A. Albert :
“New results in the theory of normal division algebras ,”
Bull. Am. Math. Soc.
36
(1930 ),
pp. 198–199 .
Abstract only; paper in Trans. Am. Math. Soc. 32 :2 (1930) .
JFM
56.0152.19
article
BibTeX
@article {key56.0152.19j,
AUTHOR = {Albert, A. A.},
TITLE = {New results in the theory of normal
division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
YEAR = {1930},
PAGES = {198--199},
DOI = {10.1090/S0002-9904-1930-04929-0},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{32}:2 (1930).
JFM:56.0152.19.},
ISSN = {0002-9904},
}
A. A. Albert :
“On direct products, cyclic division algebras, and pure Riemann matrices ,”
Proc. Natl. Acad. Sci. U.S.A.
16 : 4
(April 1930 ),
pp. 313–315 .
See also Trans. Am. Math. Soc. 33 : 1 (1931) .
JFM
56.0869.01
article
BibTeX
@article {key56.0869.01j,
AUTHOR = {Albert, A. A.},
TITLE = {On direct products, cyclic division
algebras, and pure {R}iemann matrices},
JOURNAL = {Proc. Natl. Acad. Sci. U.S.A.},
VOLUME = {16},
NUMBER = {4},
MONTH = {April},
YEAR = {1930},
PAGES = {313--315},
DOI = {10.1073/pnas.16.4.313},
NOTE = {See also \textit{Trans. Am. Math. Soc.}
\textbf{33}: 1 (1931). JFM:56.0869.01.},
ISSN = {0027-8424},
}
A. A. Albert :
“On the Wedderburn norm condition for cyclic algebras ,”
Bull. Am. Math. Soc.
36 : 11
(1930 ),
pp. 804 .
Abstract only; paper in Bull. Am. Math. Soc. 37 :4 (1931) .
JFM
56.0153.01
article
BibTeX
@article {key56.0153.01j,
AUTHOR = {Albert, A. A.},
TITLE = {On the Wedderburn norm condition for
cyclic algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {11},
YEAR = {1930},
PAGES = {804},
DOI = {10.1090/S0002-9904-1930-05060-0},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{37}:4 (1931).
JFM:56.0153.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“A necessary and sufficient condition for the non-equivalence of any two rational generalized quaternion division algebras ,”
Bull. Am. Math. Soc.
36 : 3
(1930 ),
pp. 213 .
Abstract only; paper in Bull. Am. Math. Soc. 36 :8 (1930) .
JFM
56.0152.23
article
BibTeX
@article {key56.0152.23j,
AUTHOR = {Albert, A. A.},
TITLE = {A necessary and sufficient condition
for the non-equivalence of any two rational
generalized quaternion division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {3},
YEAR = {1930},
PAGES = {213},
DOI = {10.1090/S0002-9904-1930-04929-0},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{36}:8 (1930).
JFM:56.0152.23.},
ISSN = {0002-9904},
}
A. A. Albert :
“A determination of the integers of all cubic fields ,”
Bull. Am. Math. Soc.
36 : 3
(1930 ),
pp. 199 .
Abstract only; paper in Ann. Math. 31 :4 (1930) .
JFM
56.0152.22
article
BibTeX
@article {key56.0152.22j,
AUTHOR = {Albert, A. A.},
TITLE = {A determination of the integers of all
cubic fields},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {3},
YEAR = {1930},
PAGES = {199},
DOI = {10.1090/S0002-9904-1930-04929-0},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{31}:4 (1930). JFM:56.0152.22.},
ISSN = {0002-9904},
}
A. A. Albert :
“The non-existence of pure Riemann matrices with normal multiplication algebras of order sixteen ,”
Bull. Am. Math. Soc.
36 : 3
(1930 ),
pp. 199 .
Abstract only; paper in Ann. Math. 31 :3 (1930) .
JFM
56.0152.20
article
BibTeX
@article {key56.0152.20j,
AUTHOR = {Albert, A. A.},
TITLE = {The non-existence of pure Riemann matrices
with normal multiplication algebras
of order sixteen},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {3},
YEAR = {1930},
PAGES = {199},
DOI = {10.1090/S0002-9904-1930-04929-0},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{31}:3 (1930). JFM:56.0152.20.},
ISSN = {0002-9904},
}
A. A. Albert :
“Division algebras over an algebraic field ,”
Bull. Am. Math. Soc.
37 : 10
(1931 ),
pp. 777–784 .
An abstract was published in Bull. Am. Math. Soc. 37 :7 (1931) .
MR
1562255
JFM
57.0161.01
Zbl
0003.05303
article
Abstract
BibTeX
H. Hasse has given a rigorous treatment of the theory of quadratic null forms over the field \( R \) of all rational numbers. He used the theory of \( p \) -adic numbers and readily extended his methods to obtain complete results on quadratic forms over any algebraic number field [1923] and hence, by a simple isomorphism, over any field \( R(\theta) \) , where \( \theta \) is any quantity satisfying an equation with coefficients in \( R \) and irreducible in \( R \) . Hasse has also used the fundamental principle of his quadratic form theory to prove several important theorems on cyclic (Dickson) algebras [1932].
I have recently obtained theorems on rational division algebras by the use of A. Meyer’s theorem that every indefinite quadratic form, with rational coefficients, in five or more variables is a null form. But now Hasse’s theorems make the extension to algebras over algebraic fields \( R(\theta) \) almost immediate. In particular it is shown here that the direct product of any two generalized quaternion algebras over \( R(\theta) \) is never a division algebra, and that a sufficient condition that a normal division algebra of order sixteen over \( R(\theta) \) be a cyclic algebra is that it contain a quantity \( x \) not in \( R(\theta) \) such that \( x^2 = \Delta_1^2 + \Delta_2^2 \) with \( \Delta_1 \) and \( \Delta_2 \) in \( R(\theta) \) .
Hasse’s new theorems on cyclic algebras are also used here to obtain an alternative proof of the above theorem on generalized quaternion algebras. In fact I show here that a necessary and sufficient condition that a direct product of any two normal division algebras over a field \( R(\theta) \) be a division algebra is that their orders be relatively prime.
@article {key1562255m,
AUTHOR = {Albert, A. A.},
TITLE = {Division algebras over an algebraic
field},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {10},
YEAR = {1931},
PAGES = {777--784},
DOI = {10.1090/S0002-9904-1931-05273-3},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{37}:7 (1931).
MR:1562255. Zbl:0003.05303. JFM:57.0161.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“Errata: ‘On direct products, cyclic division algebras, and pure Riemann matrices’ ,”
Trans. Am. Math. Soc.
33 : 4
(October 1931 ),
pp. 999 .
Errata for paper published in Trans. Am. Math. Soc. 33 :1 (1931) .
MR
1500511
article
BibTeX
@article {key1500511m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Errata: ``{O}n direct products, cyclic
division algebras, and pure {R}iemann
matrices''},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {33},
NUMBER = {4},
MONTH = {October},
YEAR = {1931},
PAGES = {999},
URL = {http://www.jstor.org/stable/1989520},
NOTE = {Errata for paper published in \textit{Trans.
Am. Math. Soc.} \textbf{33}:1 (1931).
MR:1500511.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“The structure of matrices with any normal division algebra of multiplications ,”
Ann. Math. (2)
32 : 1
(January 1931 ),
pp. 131–148 .
MR
1502987
JFM
57.0162.01
Zbl
0001.26603
article
Abstract
BibTeX
The outstanding problem in the theory of Riemann matrices is the determination of all pure Riemann matrices. The chief sub-problem has been that of finding the structure of a pure Rieman matrix with a given multiplication algebra. This problem was solved for the case of fields by S. Lefschetz, was reduced essentially to the case of nornal division algebras by the author, and was solved for the case of “known” normal division algebras by the author [1930].
In the present paper the author defines algebras of multiplications of matrices not necessarily Riemann matrices and finds necessary and sufficient conditions that a matrix have a given algebra of multiplications. By adding the conditions that a given matrix be a Riemann matrix having no multiplication not in the given algebra, the author completely determines the structure of all pure Riemann matrices with a given multiplication algebra.
@article {key1502987m,
AUTHOR = {Albert, A. Adrian},
TITLE = {The structure of matrices with any normal
division algebra of multiplications},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {32},
NUMBER = {1},
MONTH = {January},
YEAR = {1931},
PAGES = {131--148},
DOI = {10.2307/1968420},
NOTE = {MR:1502987. Zbl:0001.26603. JFM:57.0162.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“A note on cyclic algebras of order sixteen ,”
Bull. Am. Math. Soc.
37 : 10
(1931 ),
pp. 727–730 .
An abstract was published in Bull. Am. Math. Soc. 37 :7 (1931) .
MR
1562244
JFM
57.0160.03
Zbl
0003.05302
article
Abstract
BibTeX
In a recent paper [1931] I considered cyclic (Dickson) algebras of order sixteen generated by a cyclic quartic field \( Z \) and a quantity \( \gamma \) in the reference field \( F \) . It was proved there that if the algebra \( A \) were a division algebra and if \( \gamma^2 \) were the norm of a quantity of \( Z \) , so that the Wedderburn norm condition would not be satisfied, then \( A \) would be the direct product of two generalized quaternion algebras. It was not proved, however, that such division algebras existed.
R. Brauer has recently [1930] proved that there exist normal division algebras which are direct products of two generalized quaternion algebras. In the present note I give an example of a cyclic algebra over the Brauer reference field for which the norm condition is not satisfied, therefore completing the theory of the previous paper.
@article {key1562244m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on cyclic algebras of order sixteen},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {10},
YEAR = {1931},
PAGES = {727--730},
DOI = {10.1090/S0002-9904-1931-05249-6},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{37}:7 (1931).
MR:1562244. Zbl:0003.05302. JFM:57.0160.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“On direct products, cyclic division algebras, and pure Riemann matrices ,”
Trans. Am. Math. Soc.
33 : 1
(1931 ),
pp. 219–234 .
Errata published in Trans. Am. Math. Soc. 33 :4 (1931) . See also Proc. Natl. Acad. Sci. U.S.A. 16 :4 (1930) .
MR
1501586
JFM
57.0158.03
Zbl
0001.11602
article
Abstract
BibTeX
The present paper is the result of a consideration of several related topics in the theory of linear associative algebras and the application of the results obtained to the theory of Riemann matrices. We first consider a linear algebra problem of great importance in its application to Riemann matrix theory, the question as to when a normal division algebra of order \( n^2 \) over \( F \) is representable by an algebra of \( m \) -rowed square matrices with elements in \( F \) . It is shown that this is possible if and only if \( n^2 \) divides \( m \) and this is applied to prove that.
The multiplication index \( h \) of a pure Riemann matrix of genus \( p \) is a divisor of \( 2p \) .
The algebras called cyclic (Dickson) algebras are the simplest normal division algebras structurally. J. H. M. Wedderburn has given sufficient conditions that constructed cyclic algebras be division algebras but it seems to have been overlooked that these conditions have not been shown to be necessary. In the fundamental problem of the construction of all such division algebras necessary and sufficient conditions are of course needed. The question of the necessity of the Wedderburn conditions is considered here and the results applied to obtain what seems a remarkable restriction on the types of algebras which may be the multiplication algebras of pure Riemann matrices. Also certain general theorems on direct products of normal simple algebras are proved and the conclusions used to reduce the problem of the construction of cyclic division algebras to the case where the order of the algebra is a power of a single prime.
@article {key1501586m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On direct products, cyclic division
algebras, and pure {R}iemann matrices},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {33},
NUMBER = {1},
YEAR = {1931},
PAGES = {219--234},
DOI = {10.2307/1989468},
NOTE = {Errata published in \textit{Trans. Am.
Math. Soc.} \textbf{33}:4 (1931). See
also \textit{Proc. Natl. Acad. Sci.
U.S.A.} \textbf{16}:4 (1930). MR:1501586.
Zbl:0001.11602. JFM:57.0158.03.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“On normal division algebras of type \( R \) in thirty-six units ,”
Trans. Am. Math. Soc.
33 : 1
(January 1931 ),
pp. 235–243 .
MR
1501587
JFM
57.0160.01
Zbl
0001.11701
article
Abstract
BibTeX
A normal division algebra in \( n^2 \) units over a modular field \( F \) is of type \( R \) if it contains a quantity \( i \) whose minimum equation with respect to \( F \) , \( \phi(\omega) = 0 \) , has degree \( n \) and \( n \) distinct roots which are polynomials in \( i \) with coefficients in \( F \) . Algebras of type \( R \) occupy a central position in the theory of division algebras as they are the only normal division algebras whose structure is known, and all division algebras of order less than twenty-five are expressible as algebras of type \( R \) .
The normal division algebras \( D \) whose structure is the simplest are those for the case where \( \phi(\omega)=0 \) has the cyclic group with respect to \( F \) . When \( n \) is six and \( \phi(\omega)=0 \) is cyclic, \( D \) is expressible as the direct product of a generalized quaternion division algebra and a cyclic division algebra of order nine, while conversely every such direct product is a cyclic division algebra of order thirty-six. The group of \( \phi(\omega) = 0 \) is evidently regular and hence the only other type of equation to be considered for algebras of order thirty-six and type \( R \) is one which as the single non-cyclic, non-abelian regular group on six letters, a case giving a very complicated algebra.
It has never been demonstrated that there exist normal division algebras which are not cyclic algebras. The author showed, in a recent paper [1930], that the algebras which had been constructed by F. Cecioni [1923] and which were based on a non-cyclic quartic were cyclic algebras. We show here that all normal division algebras of type \( R \) in thirty-six units are cyclic algebras .
@article {key1501587m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On normal division algebras of type
\$R\$ in thirty-six units},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {33},
NUMBER = {1},
MONTH = {January},
YEAR = {1931},
PAGES = {235--243},
DOI = {10.2307/1989469},
NOTE = {MR:1501587. Zbl:0001.11701. JFM:57.0160.01.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“On the Wedderburn norm condition for cyclic algebras ,”
Bull. Am. Math. Soc.
37 : 4
(1931 ),
pp. 301–312 .
An abstract was published in Bull. Am. Math. Soc. 36 :11 (1930) .
MR
1562142
JFM
57.0160.02
Zbl
0001.26701
article
Abstract
BibTeX
In the present paper cyclic algebras of order sixteen with the corresponding cyclic quartic in its canonical form [Garver 1928]
\[ \phi(\omega) \equiv \omega^4 + 2\nu(1+\Delta^2)\omega^2 + \nu^2\Delta^2(1+\Delta^2) = 0 \]
such that \( \nu \) and \( \Delta \) are in \( F \) , and \( \tau = 1+\Delta^2 \) is not the square of any quantity of \( F \) , are considered. The norm \( N(a) \) of a polynomial in \( i \) is a rather complicated quartic form in four variables, yet we can secure the result that \( \gamma^2 = N(a) \) if and only if \( \gamma = \alpha^2 - \beta^2\tau \) for \( \alpha \) and \( \beta \) in \( F \) , a curious property of cyclic quartic fields. When the above equation is satisfied the algebra \( A \) is expressible as a direct product of two generalized quaternion algebras. Necessary and sufficient conditions are secured that our algebras \( A \) of order sixteen be division algebras, and it is shown that for the particularly interesting case where \( F \) is the field of all rational numbers the Wedderburn condition is necessary as well as sufficient .
@article {key1562142m,
AUTHOR = {Albert, A. A.},
TITLE = {On the {W}edderburn norm condition for
cyclic algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {4},
YEAR = {1931},
PAGES = {301--312},
DOI = {10.1090/S0002-9904-1931-05158-2},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{36}:11 (1930).
MR:1562142. Zbl:0001.26701. JFM:57.0160.02.},
ISSN = {0002-9904},
}
A. A. Albert :
“On direct products ,”
Trans. Am. Math. Soc.
33 : 3
(1931 ),
pp. 690–711 .
An abstract was published in Bull. Am. Math. Soc. 37 :5 (1931) .
MR
1501610
JFM
57.0159.01
Zbl
0002.24605
article
Abstract
BibTeX
The principal contribution of this article is a set of theorems on the structure of the direct product of a normal division algebra \( A \) over \( F \) and an algebraic field \( F(\eta) \) , with applications of the Galois theory of equations. The theorems are useful new tools for research on normal division algebras. In particular it is shown that it is possible to extend the reference field \( F \) of any normal division algebra \( A \) of order \( p^2 \) over \( F \) , \( p \) a prime, such that
\[ A^{\prime} = A\times F(\eta) \]
is a cyclic normal divison algebra over \( F(\eta) \) . A new proof is given of a little known theorem of R. Brauer [1929] which reduces the problem of determinining all normal division algebras of order \( n^2 \) over \( F \) to the case where \( n \) is a power of a prime.
@article {key1501610m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On direct products},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {33},
NUMBER = {3},
YEAR = {1931},
PAGES = {690--711},
DOI = {10.2307/1989332},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{37}:5 (1931).
MR:1501610. Zbl:0002.24605. JFM:57.0159.01.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“Normal division algebras of order \( 2^{2^m} \) ,”
Proc. Natl. Acad. Sci. USA
17 : 6
(June 1931 ),
pp. 389–392 .
JFM
57.0161.02
Zbl
0002.11502
article
BibTeX
@article {key0002.11502z,
AUTHOR = {Albert, A. A.},
TITLE = {Normal division algebras of order \$2^{2^m}\$},
JOURNAL = {Proc. Natl. Acad. Sci. USA},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {17},
NUMBER = {6},
MONTH = {June},
YEAR = {1931},
PAGES = {389--392},
URL = {http://www.pnas.org/content/17/6/389.full.pdf+html},
NOTE = {Zbl:0002.11502. JFM:57.0161.02.},
ISSN = {0027-8424},
}
A. A. Albert :
“The structure of pure Riemann matrices with non-commutative multiplication algebras ,”
Rend. Circ. Mat. Palermo
55 : 1
(1931 ),
pp. 57–115 .
JFM
57.0161.03
Zbl
0001.26602
article
Abstract
BibTeX
The chief outstanding problem in the theory of Riemann matrices is the determination of the structure of all pure Riemann matrices \( \omega \) with a given non-commutative division algebra \( B \) as its multiplication algebra \( D \) .
In the present paper we shall consider pure Riemann matrices over any sub-field of the field of all real numbers, an extension of ordinary theory which is given in terms of the field of all rational numbers. This extension is made necessary when we consider submatrices of ordinary pure Riemann matrices. We give a rigorous algebraic proof of Rosatti’s main results [1929] and obtain his theorems, not in terms of unknown sub-algebras of given algebras \( B \) but actually in terms of the central field of \( B \) and its rank function. The criteria we obtain are in terms of concrete properties of the algebras to be considered and are therefore immediately applicable to restrict the class of algebras which may possibly be multiplication algebras.
@article {key0001.26602z,
AUTHOR = {Albert, A. A.},
TITLE = {The structure of pure {R}iemann matrices
with non-commutative multiplication
algebras},
JOURNAL = {Rend. Circ. Mat. Palermo},
FJOURNAL = {Rendiconti del Circolo Matematico di
Palermo},
VOLUME = {55},
NUMBER = {1},
YEAR = {1931},
PAGES = {57--115},
DOI = {10.1007/BF03016787},
NOTE = {Zbl:0001.26602. JFM:57.0161.03.},
ISSN = {1973-4409},
}
A. A. Albert :
“A note on cyclic algebras of order sixteen ,”
Bull. Am. Math. Soc.
37 : 7
(1931 ),
pp. 527–528 .
Abstract only; paper in Bull. Am. Math. Soc. 37 :10 (1931) .
JFM
57.0172.01
article
BibTeX
@article {key57.0172.01j,
AUTHOR = {Albert, A. A.},
TITLE = {A note on cyclic algebras of order sixteen},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {7},
YEAR = {1931},
PAGES = {527--528},
DOI = {10.1090/S0002-9904-1931-05182-X},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{37}:10 (1931).
JFM:57.0172.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“On the construction of cyclic algebras with a given exponent ,”
Bull. Am. Math. Soc.
37 : 7
(1931 ),
pp. 528 .
Abstract only; paper in Am. J. Math. 54 :1 (1932) .
JFM
57.0172.02
article
BibTeX
@article {key57.0172.02j,
AUTHOR = {Albert, A. A.},
TITLE = {On the construction of cyclic algebras
with a given exponent},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {7},
YEAR = {1931},
PAGES = {528},
DOI = {10.1090/S0002-9904-1931-05182-X},
NOTE = {Abstract only; paper in \textit{Am.
J. Math.} \textbf{54}:1 (1932). JFM:57.0172.02.},
ISSN = {0002-9904},
}
A. A. Albert :
“The integers represented by sets of positive ternary quadratic forms ,”
Bull. Am. Math. Soc.
37 : 3
(1931 ),
pp. 169 .
Abstract only; paper in Am. J. Math. 55 :1–4 (1933) .
JFM
57.0199.08
article
BibTeX
@article {key57.0199.08j,
AUTHOR = {Albert, A. A.},
TITLE = {The integers represented by sets of
positive ternary quadratic forms},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {3},
YEAR = {1931},
PAGES = {169},
DOI = {10.1090/S0002-9904-1931-05124-7},
NOTE = {Abstract only; paper in \textit{Am.
J. Math.} \textbf{55}:1--4 (1933). JFM:57.0199.08.},
ISSN = {0002-9904},
}
A. A. Albert :
“On direct products ,”
Bull. Am. Math. Soc.
37 : 5
(1931 ),
pp. 355 .
Abstract only; paper in Trans. Am. Math. Soc. 33 :3 (1931) .
JFM
57.0171.22
article
BibTeX
@article {key57.0171.22j,
AUTHOR = {Albert, A. A.},
TITLE = {On direct products},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {5},
YEAR = {1931},
PAGES = {355},
DOI = {10.1090/S0002-9904-1931-05146-6},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{33}:3 (1931).
JFM:57.0171.22.},
ISSN = {0002-9904},
}
A. A. Albert :
“Division algebras over an algebraic field ,”
Bull. Am. Math. Soc.
37 : 7
(1931 ),
pp. 528 .
Abstract only; paper in Bull. Am. Math. Soc. 37 :10 (1931) .
JFM
57.0172.03
article
BibTeX
@article {key57.0172.03j,
AUTHOR = {Albert, A. A.},
TITLE = {Division algebras over an algebraic
field},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {7},
YEAR = {1931},
PAGES = {528},
DOI = {10.1090/S0002-9904-1931-05182-X},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{37}:10 (1931).
JFM:57.0172.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“Algebras of degree \( 2^e \) and pure Riemann matrices ,”
Ann. Math. (2)
33 : 2
(April 1932 ),
pp. 311–318 .
MR
1503054
JFM
58.0143.02
Zbl
0004.10001
article
Abstract
BibTeX
The most recent discoveries in the theory of linear associative algebras have been due to the discussion of a new invariant number, the exponent of a normal division algebra. If \( A \) is any normal division algebra of degree \( n \) (order \( n^2 \) ) over \( F \) then the exponent of \( A \) is the least integer \( \rho \) such that \( A^{\rho} \) is a total matric algebra. H. Hasse has shown that the exponent of any cyclic algebra over an algebraic field \( \Omega \) is equal to its degree. In the present paper I consider the corresponding question for any normal division algebra of degree a power of two over an algebraic field and prove that here again the exponent is equal to the degree. In particular I obtain the important theorem that the only self-reciprocal normal division algebras over an algebraic field are algebras of degree one or two .
The principal problem in the closely related theories of the complex multiplication of Riemann matrices, singular correspondences between algebraic curves, algebraic correspondences on an abelian variety, is that of a determination of the multiplication algebra \( D \) of any pure Riemann matrix. This algebra is a normal division algebra over an algebraic field. Either this field \( \Omega = R(s) \) where \( R \) is the field of all rational numbers and \( s \) is a quantity the roots \( \sigma_1,\dots,\sigma_t \) of whose minimum equation are all real, or \( \Omega = R(q,s) \) where \( s \) is as before and \( q^2 = \mu(s) \) such that \( \mu(\sigma_j) < 0 \) . I have called a Riemann matrix \( \omega \) of the first or second kind according as \( \Omega = R(s) \) or \( \Omega = R(q,s) \) . As an immediate corollary of my theorem of self-reciprocal algebras I show here that the multiplication algebra of any Riemann matrix of the first kind is either a field \( R(s) \) or a generalized quaternion algebra over \( R(s) \) .
@article {key1503054m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Algebras of degree \$2^e\$ and pure {R}iemann
matrices},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {33},
NUMBER = {2},
MONTH = {April},
YEAR = {1932},
PAGES = {311--318},
DOI = {10.2307/1968332},
NOTE = {MR:1503054. Zbl:0004.10001. JFM:58.0143.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“Normal division algebras of degree four over an algebraic field ,”
Trans. Am. Math. Soc.
34 : 2
(1932 ),
pp. 363–372 .
MR
1501642
JFM
58.0144.01
Zbl
0004.10002
article
Abstract
BibTeX
The most important algebras for their applications are normal division algebras of degree \( n \) (order \( n^2 \) ) over an algebraic field \( R(\theta) \) , where \( R \) is the field of all rational numbers and \( \theta \) is a root of an equation with rational coefficients and irreducible in \( R \) . All normal division algebras of degree two and three have been shown to be cyclic (Dickson) algebras [Dickson 1927], [Wedderburn 1921]. In the following sections the author will prove that all normal division algebras of degree four (order sixteen) over \( R(\theta) \) are cyclic (Dickson) algebras.
@article {key1501642m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Normal division algebras of degree four
over an algebraic field},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {34},
NUMBER = {2},
YEAR = {1932},
PAGES = {363--372},
DOI = {10.2307/1989546},
NOTE = {MR:1501642. Zbl:0004.10002. JFM:58.0144.01.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“On normal simple algebras ,”
Trans. Am. Math. Soc.
34 : 3
(1932 ),
pp. 620–625 .
An abstract was published in Bull. Am. Math. Soc. 38 :3 .
MR
1501653
JFM
58.1026.04
Zbl
0005.05002
article
Abstract
BibTeX
Recently published theorems on the direct product of a normal division algebra \( D \) of degree \( m \) (order \( m^2 \) ) over \( F \) and an algebraic field \( Z \) of degree (order) \( r \) over \( F \) have proved to be very important tools for research on division algebras. Of particular value is the use of an integer \( s \) called the index reduction factor of \( D\times Z \) . In the present paper new light is thrown on the properties of \( s \) by a study of an integer \( q = q(Z,D) \) called the quotient index of \( Z \) and \( D \) . This \( q \) is the least integer such that the direct product of \( D \) and a total matric algebra of degree \( q \) contains a sub-field equivalent to \( Z \) . It is proved that \( r=sq \) . The results obtained are also applied to prove an important conjecture of L. E. Dickson made by him in 1926, the so-called norm condition that a certain type of algebra be a division algebra.
@article {key1501653m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On normal simple algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {34},
NUMBER = {3},
YEAR = {1932},
PAGES = {620--625},
DOI = {10.2307/1989369},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{38}:3. MR:1501653.
Zbl:0005.05002. JFM:58.1026.04.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“On the construction of cyclic algebras with a given exponent ,”
Am. J. Math.
54 : 1
(1932 ),
pp. 1–13 .
An abstract was published in Bull. Am. Math. Soc. 37 :7 (1931) .
MR
1506868
JFM
58.0141.05
Zbl
0003.24405
article
Abstract
BibTeX
In this note it is proved that there exist cyclic normal division algebras of order sixteen over a field \( R(x,y) \) , \( x \) and \( y \) indeterminates, such that the algebras do not satisfy the Wedderburn norm condition for cyclic algebras and are direct products of generalized quaternion algebras. This example is a modification of an example of R. Brauer in that he also considered division algebras which were such direct products over such a field but these algebras are cyclic and moreover the proof that these algebras are division algebras is essentially different from his.
@article {key1506868m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On the construction of cyclic algebras
with a given exponent},
JOURNAL = {Am. J. Math.},
FJOURNAL = {American Journal of Mathematics},
VOLUME = {54},
NUMBER = {1},
YEAR = {1932},
PAGES = {1--13},
DOI = {10.2307/2371072},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{37}:7 (1931).
MR:1506868. Zbl:0003.24405. JFM:58.0141.05.},
ISSN = {0002-9327},
CODEN = {AJMAAN},
}
A. A. Albert and H. Hasse :
“A determination of all normal division algebras over an algebraic number field ,”
Trans. Am. Math. Soc.
34 : 3
(1932 ),
pp. 722–726 .
An abstract was published in Bull. Am. Math. Soc. 38 :3 (1932) .
MR
1501659
Zbl
0005.05003
article
Abstract
People
BibTeX
The principal problem in the theory of linear algebras is that of the determination of all normal division algebras (of order \( n^2 \) , degree \( n \) ) over a field \( F \) . The most important special case of this problem is the case where \( F \) is an algebraic number field of finite degree . It is already known that for \( n = 2 \) [Dickson 1927, p. 45], \( n = 3 \) [Wedderburn 1921], \( n = 4 \) [Albert 1932] all such algebras are cyclic. We shall prove here a principal theorem on algebras over algebraic number fields:
Every normal division algebra over an algebraic number field of finite degree is a cyclic (Dickson) algebra.
@article {key1501659m,
AUTHOR = {Albert, A. Adrian and Hasse, Helmut},
TITLE = {A determination of all normal division
algebras over an algebraic number field},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {34},
NUMBER = {3},
YEAR = {1932},
PAGES = {722--726},
DOI = {10.2307/1989375},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{38}:3 (1932).
MR:1501659. Zbl:0005.05003.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“A construction of non-cyclic normal division algebras ,”
Bull. Am. Math. Soc.
38 : 6
(1932 ),
pp. 449–456 .
An abstract was published in Bull. Am. Math. Soc. 38 :3 (1932) .
MR
1562415
JFM
58.0143.01
Zbl
0005.00603
article
Abstract
BibTeX
We know now that every normal division algebra over an algebraic number field is a cyclic (Dickson) algebra. This result was proved by highly refined arithmetic means and the proof cannot be extended to obtain a like result for algebras over a general field. The very important question of whether or not any non-cyclic algebras exist has thus remained unanswered up to the present.
I shall give a construction of non-cyclic algebras of order sixteen over a function field in this paper. These algebras will be proved to be normal envision algebras; they furnish the first example in the literature of linear associative algebras of division algebras definitely known to be not of the Dickson type.
@article {key1562415m,
AUTHOR = {Albert, A. A.},
TITLE = {A construction of non-cyclic normal
division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {38},
NUMBER = {6},
YEAR = {1932},
PAGES = {449--456},
DOI = {10.1090/S0002-9904-1932-05420-9},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{38}:3 (1932).
MR:1562415. Zbl:0005.00603. JFM:58.0143.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“A note on normal division algebras of order sixteen ,”
Bull. Am. Math. Soc.
38 : 10
(1932 ),
pp. 703–706 .
An abstract was published in Bull. Am. Math. Soc. 38 :7 (1932) .
MR
1562492
JFM
58.0141.03
Zbl
0005.34202
article
Abstract
BibTeX
I have proved [1929] that every normal division algebra of order sixteen over any non-modular field \( F \) contains a quartic field with \( G_4 \) group. This important result gave a determination of all normal division algebras of order sixteen . I have recently proved [1932; 1933] the existence of non-cyclic normal division algebras, so that the result mentioned above is actually the best possible result. However, my proof of 1929 is long and complicated and the above result there obtained is of sufficient importance to make a better proof desirable. It is the purpose of this note to provide such a proof.
@article {key1562492m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on normal division algebras of
order sixteen},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {38},
NUMBER = {10},
YEAR = {1932},
PAGES = {703--706},
DOI = {10.1090/S0002-9904-1932-05505-7},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{38}:7 (1932).
MR:1562492. Zbl:0005.34202. JFM:58.0141.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“A note on normal division algebras of order sixteen ,”
Bull. Am. Math. Soc.
38 : 7
(1932 ),
pp. 496 .
Abstract only; paper in Bull. Am. Math. Soc. 38 :10 (1932) .
JFM
58.0153.05
article
BibTeX
@article {key58.0153.05j,
AUTHOR = {Albert, A. A.},
TITLE = {A note on normal division algebras of
order sixteen},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {38},
NUMBER = {7},
YEAR = {1932},
PAGES = {496},
DOI = {10.1090/S0002-9904-1932-05458-1},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{38}:10 (1932).
JFM:58.0153.05.},
ISSN = {0002-9904},
}
A. A. Albert :
“On normal simple algebras ,”
Bull. Am. Math. Soc.
38 : 3
(1932 ),
pp. 179–180 .
Abstract only; paper in Trans. Am. Math. Soc. 34 :3 (1932) .
JFM
58.0153.01
article
BibTeX
@article {key58.0153.01j,
AUTHOR = {Albert, A. A.},
TITLE = {On normal simple algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {38},
NUMBER = {3},
YEAR = {1932},
PAGES = {179--180},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{34}:3 (1932).
JFM:58.0153.01.},
ISSN = {0002-9904},
}
A. A. Albert and H. Hasse :
“A determination of all normal division algebras over an algebraic number field ,”
Bull. Am. Math. Soc.
38 : 3
(1932 ),
pp. 179 .
Abstract only; paper in Trans. Am. Math. Soc. 34 :3 (1932) .
JFM
58.0153.02
article
People
BibTeX
@article {key58.0153.02j,
AUTHOR = {Albert, A. Adrian and Hasse, Helmut},
TITLE = {A determination of all normal division
algebras over an algebraic number field},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {38},
NUMBER = {3},
YEAR = {1932},
PAGES = {179},
DOI = {10.1090/S0002-9904-1932-05369-1},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{34}:3 (1932).
JFM:58.0153.02.},
ISSN = {0002-9904},
}
A. A. Albert :
“A construction of non-cyclic normal division algebras ,”
Bull. Am. Math. Soc.
38 : 3
(1932 ),
pp. 180–181 .
Abstract only; paper in Bull. Am. Math. Soc. 38 :6 (1932) .
JFM
58.0153.03
article
BibTeX
@article {key58.0153.03j,
AUTHOR = {Albert, A. A.},
TITLE = {A construction of non-cyclic normal
division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {38},
NUMBER = {3},
YEAR = {1932},
PAGES = {180--181},
DOI = {10.1090/S0002-9904-1932-05369-1},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{38}:6 (1932).
JFM:58.0153.03.},
ISSN = {0002-9904},
}
A. A. Albert :
“The integers represented by sets of ternary quadratic forms ,”
Am. J. Math.
55 : 1–4
(1933 ),
pp. 274–292 .
An abstract was published in Bull. Am. Math. Soc. 37 :3 (1931) .
MR
1506964
JFM
59.0181.03
Zbl
0006.29004
article
Abstract
BibTeX
One of the most interesting topics in the theory of numbers is the study of the question of what integers are represented by positive ternary quadratic forms. Few general theorems are known in this subject. In fact, as L. E. Dickson has indicated, most of the forms are irregular [1926-27].
In the present paper a consideration is made of a different type of problem yet one that throws a good deal of light on the above topic. The problem of determining all the integers represented by the set \( \Sigma(d) \) of all positive ternary quadratic forms of the same determinant \( d \) is studied here and a complete solution is obtained. Moreover the results have the following remarkably simple form.
@article {key1506964m,
AUTHOR = {Albert, A. Adrian},
TITLE = {The integers represented by sets of
ternary quadratic forms},
JOURNAL = {Am. J. Math.},
FJOURNAL = {American Journal of Mathematics},
VOLUME = {55},
NUMBER = {1--4},
YEAR = {1933},
PAGES = {274--292},
DOI = {10.2307/2371130},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{37}:3 (1931).
MR:1506964. Zbl:0006.29004. JFM:59.0181.03.},
ISSN = {0002-9327},
CODEN = {AJMAAN},
}
A. A. Albert :
“Normal division algebras over algebraic number fields not of finite degree ,”
Bull. Am. Math. Soc.
39 : 10
(1933 ),
pp. 746–749 .
An abstract was published in Bull. Am. Math. Soc. 39 :9 (1933) .
MR
1562722
JFM
59.0159.02
Zbl
0008.00104
article
Abstract
BibTeX
If \( R \) is the field of all rational numbers and if \( \xi_1,\dots,\xi_n \) are ordinary algebraic numbers, then the field
\[ \Omega = R(\xi_1,\dots,\xi_n) \]
of all rational functions with rational coefficients of \( \xi_1,\dots,\xi_n \) is an algebraic number field of finite degree (the maximum number of linearly independent quantities of \( \Omega \) ) over \( R \) . It has recently been proved [Albert and Hasse 1932] that every normal simple algebra over such a field \( \Omega \) is cyclic. In particular it has been shown that every normal division algebra of order \( n^2 \) (degree \( n \) ) over \( \Omega \) is cyclic and has exponent \( n \) .
In the present note I shall give an extension of the above results to normal division algebras over any algebraic number field \( \Lambda \) . I shall prove that all normal division algebras over \( \Lambda \) are cyclic and with degree equal to exponent but shall give a trivial example showing that the theorem corresponding to the above on normal simple algebras is false. The problem of the equivalence of normal division algebras over \( \Lambda \) will also be discussed.
@article {key1562722m,
AUTHOR = {Albert, A. A.},
TITLE = {Normal division algebras over algebraic
number fields not of finite degree},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {10},
YEAR = {1933},
PAGES = {746--749},
DOI = {10.1090/S0002-9904-1933-05725-7},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:9 (1933).
MR:1562722. Zbl:0008.00104. JFM:59.0159.02.},
ISSN = {0002-9904},
}
A. A. Albert :
“Cyclic fields of degree eight ,”
Trans. Am. Math. Soc.
35 : 4
(1933 ),
pp. 949–964 .
An abstract was published in Bull. Am. Math. Soc. 39 :1 (1933) .
MR
1501727
JFM
59.0158.03
Zbl
0008.00201
article
Abstract
BibTeX
Let \( F \) be any non-modular field, \( C \) be an algebraic extension of degree \( n \) of \( F \) . Then \( C=F(x) \) is the field of all rational functions with coefficients in \( F \) of a root \( x \) of an equation \( \phi(\omega)=0 \) which has coefficients in \( F \) , degree \( n \) , and transitive group \( G \) for \( F \) .
The problem of the construction of all equations of degree \( n \) and group \( G \) is evidently equivalent to the problem of the construction of all corresponding fields \( C \) . Moreover the construction of a set of canonical equations \( \psi(\omega) = 0 \) with the property that every \( C=F(x) \) of degree \( n \) and group \( G \) is equal to an \( F(y) \) defined by a \( \psi(\omega) = 0 \) provides a solution of both problems.
One of the most important problems in the algebraic theory of fields is the construction of all cyclic fields of degree \( n \) over \( F \) . This is the case where \( G \) consists of the \( n \) distinct powers \( S^i \) (\( i = 0 \) , \( 1,\dots, n-1 \) ) of a single substitution \( S \) . In this case \( G \) is also the group of all automorphisms of \( C \) . Moreover this problem has been reduced to the case \( n = p^e \) , \( p \) a prime.
Cyclic fields of degree 2, \( 2^2 \) have been constructed. In the present paper we shall use purely algebraic methods to construct all cyclic fields of degree \( 2^3 = 8 \) [Mertens 1916] over any non-modular field \( F \) .
@article {key1501727m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Cyclic fields of degree eight},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {35},
NUMBER = {4},
YEAR = {1933},
PAGES = {949--964},
DOI = {10.2307/1989602},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:1 (1933).
MR:1501727. Zbl:0008.00201. JFM:59.0158.03.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“A note on the Dickson theorem on universal ternaries ,”
Bull. Am. Math. Soc.
39 : 8
(1933 ),
pp. 585–588 .
MR
1562680
JFM
59.0181.02
Zbl
0007.33704
article
Abstract
BibTeX
A form \( f \) with integer coefficients in integer variables is called universal if it represents all positive and negative integers. Evidently, since \( f \) is homogeneous, it represents zero for the variables all zero. In case \( f = 0 \) for integral values of the variables not all zero \( f \) is called a zero form.
L. E. Dickson [1930] has given a number-theoretic proof of his theorem that every universal ternary quadratic form is a zero form . But his proof is highly technical and consequently quite long and complicated. In the present note I shall give an almost trivial rational proof of Dickson’s result. I shall also prove a generalization of his theorem for ternaries over any nonmodular field \( F \) .
@article {key1562680m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on the {D}ickson theorem on universal
ternaries},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {8},
YEAR = {1933},
PAGES = {585--588},
DOI = {10.1090/S0002-9904-1933-05684-7},
NOTE = {MR:1562680. Zbl:0007.33704. JFM:59.0181.02.},
ISSN = {0002-9904},
}
A. A. Albert :
“Non-cyclic algebras of degree and exponent four ,”
Trans. Am. Math. Soc.
35 : 1
(1933 ),
pp. 112–121 .
MR
1501674
JFM
59.0158.02
Zbl
0006.15103
article
Abstract
BibTeX
I have recently [1932] proved the existence of non-cyclic normal division algebras. The algebras I constructed are algebras \( A \) of order sixteen (degree four, so that every quantity of \( A \) is contained in some quartic sub-field of \( A \) ) containing no cyclic quartic sub-field and hence not of the cyclic (Dickson) type. But each \( A \) is expressible as a direct product of two (cyclic) algebras of degree two (order four). Hence the question of the existence of non-cyclic algebras not direct products of cyclic algebras, and therefore of essentially more complex structures than cyclic algebras, has remained unanswered.
The exponent of a normal division algebra \( A \) is the least integer \( e \) such that \( A^e \) is a total matric algebra. A normal division algebra of degree four has exponent two or four according as it is or is not expressible as a direct product of algebras of degree two. I shall prove here that there exist non-cyclic normal division algebras of degree and exponent four, algebras of a more complex structure than any previously constructed normal division algebras.
@article {key1501674m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Non-cyclic algebras of degree and exponent
four},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {35},
NUMBER = {1},
YEAR = {1933},
PAGES = {112--121},
DOI = {10.2307/1989315},
NOTE = {MR:1501674. Zbl:0006.15103. JFM:59.0158.02.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“On universal sets of positive ternary quadratic forms ,”
Ann. Math. (2)
34 : 4
(October 1933 ),
pp. 875–878 .
MR
1503139
JFM
59.0181.04
Zbl
0007.39204
article
Abstract
BibTeX
One of the most interesting topics in the Theory of Numbers is the theory of universal forms , that is forms representing all positive integers. No positive ternary quadratic form represents all positive integers, so that there can be no theory of universal positive ternaries. But this theory may be replaced by a theory of universal sets of a finite number of forms . It is my purpose, in the present article, to introduce such a new theory and to solve perhaps the first problem.
@article {key1503139m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On universal sets of positive ternary
quadratic forms},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {34},
NUMBER = {4},
MONTH = {October},
YEAR = {1933},
PAGES = {875--878},
DOI = {10.2307/1968705},
NOTE = {MR:1503139. Zbl:0007.39204. JFM:59.0181.04.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“On primary normal division algebras of degree eight ,”
Bull. Am. Math. Soc.
39 : 4
(1933 ),
pp. 265–272 .
An abstract was published in Bull. Am. Math. Soc. 39 :1 (1933) .
MR
1562597
JFM
59.0159.01
Zbl
0007.05503
article
Abstract
BibTeX
A normal division algebra \( A \) of degree \( n \) over \( F \) will be called primary if \( A \) is not expressible as a direct product of two normal division algebras \( B \) and \( C \) , where neither \( B \) nor \( C \) has degree unity. It is well known that necessarily \( n = p^e \) , \( p \) a prime, if \( A \) is primary. Moreover, if \( n = p^e \) , then a sufficient condition that \( A \) be primary is that \( A \) shall have exponent \( n \) .
I have recently proved [1932] that if \( A \) has degree four then \( A \) is primary if and only if \( A \) has exponent four. In the present paper I shall prove that there exist primary (cyclic) normal division algebras of degree eight but exponent four so that the above sufficient condition is actually not necessary.
@article {key1562597m,
AUTHOR = {Albert, A. A.},
TITLE = {On primary normal division algebras
of degree eight},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {4},
YEAR = {1933},
PAGES = {265--272},
DOI = {10.1090/S0002-9904-1933-05608-2},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:1 (1933).
MR:1562597. Zbl:0007.05503. JFM:59.0159.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“A note on the equivalence of algebras of degree two ,”
Bull. Am. Math. Soc.
39 : 4
(1933 ),
pp. 257–258 .
An abstract was published in Bull. Am. Math. Soc. 39 :3 (1933) .
MR
1562594
JFM
59.0158.04
Zbl
0007.05502
article
Abstract
BibTeX
The simplest type of normal simple algebra over any nonmodular field \( F \) is the cyclic algebra of degree two (order four)
\begin{gather*} Q(\alpha,\beta) = (1,i,j,ij),\\ ji = -ij, \quad i^2 = \alpha \neq 0, \quad j^2 = \beta \neq 0, \end{gather*}
(\( \alpha \) and \( \beta \) in \( F \) ), the so-called generalized quaternion algebra over \( F \) . Of great importance in the theory of linear algebras is the problem of finding conditions that two given normal simple algebras of the same degree shall be equivalent. But this problem has not, as yet, been explicitly solved even for the above simplest case of algebras of degree two except when \( F \) is an algebraic field [Albert 1930; Hasse 1932]. The purpose of this brief note is to give a simplification of my own previous results for rational algebras of degree two and thereby to give simple explicit conditions that any two generalized quaternion algebras over any non-modular field \( F \) shall be equivalent.
@article {key1562594m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on the equivalence of algebras
of degree two},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {4},
YEAR = {1933},
PAGES = {257--258},
DOI = {10.1090/S0002-9904-1933-05603-3},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:3 (1933).
MR:1562594. Zbl:0007.05502. JFM:59.0158.04.},
ISSN = {0002-9904},
}
A. A. Albert :
“On certain imprimitive fields of degree \( p^2 \) over \( P \) of characteristic \( p \) ,”
Bull. Am. Math. Soc.
39 : 11
(1933 ),
pp. 870 .
Abstract only; paper in Ann. Math. 35 :2 (1934) .
JFM
59.0168.20
article
BibTeX
@article {key59.0168.20j,
AUTHOR = {Albert, A. A.},
TITLE = {On certain imprimitive fields of degree
\$p^2\$ over \$P\$ of characteristic \$p\$},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {11},
YEAR = {1933},
PAGES = {870},
DOI = {10.1090/S0002-9904-1933-05751-8},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{35}:2 (1934). JFM:59.0168.20.},
ISSN = {0002-9904},
}
A. A. Albert :
“On universal sets of positive ternary quadratic forms ,”
Bull. Am. Math. Soc.
39 : 5
(1933 ),
pp. 345–346 .
Abstract only; paper in Ann. Math. 34 :4 (1933) .
JFM
59.0187.07
article
BibTeX
@article {key59.0187.07j,
AUTHOR = {Albert, A. A.},
TITLE = {On universal sets of positive ternary
quadratic forms},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {5},
YEAR = {1933},
PAGES = {345--346},
DOI = {10.1090/S0002-9904-1933-05620-3},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{34}:4 (1933). JFM:59.0187.07.},
ISSN = {0002-9904},
}
A. A. Albert :
“Integral domains of rational generalized quaternion algebra ,”
Bull. Am. Math. Soc.
39 : 7
(1933 ),
pp. 501 .
Abstract only; paper in Bull. Am. Math. Soc. 40 :2 (1934) .
JFM
59.0168.18
article
BibTeX
@article {key59.0168.18j,
AUTHOR = {Albert, A. A.},
TITLE = {Integral domains of rational generalized
quaternion algebra},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {7},
YEAR = {1933},
PAGES = {501},
DOI = {10.1090/S0002-9904-1933-05674-4},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{40}:2 (1934).
JFM:59.0168.18.},
ISSN = {0002-9904},
}
A. A. Albert :
“Normal division algebras over a modular field ,”
Bull. Am. Math. Soc.
39 : 11
(1933 ),
pp. 870–871 .
Abstract only; paper in Trans. Am. Math. Soc. 36 :2 (1934) .
JFM
59.0168.22
article
BibTeX
@article {key59.0168.22j,
AUTHOR = {Albert, A. A.},
TITLE = {Normal division algebras over a modular
field},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {11},
YEAR = {1933},
PAGES = {870--871},
DOI = {10.1090/S0002-9904-1933-05751-8},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{36}:2 (1934).
JFM:59.0168.22.},
ISSN = {0002-9904},
}
A. A. Albert :
“On primary normal division algebras of degree eight ,”
Bull. Am. Math. Soc.
39 : 1
(1933 ),
pp. 41 .
Abstract only; paper in Bull. Am. Math. Soc. 39 :4 (1933) .
JFM
59.0168.15
article
BibTeX
@article {key59.0168.15j,
AUTHOR = {Albert, A. A.},
TITLE = {On primary normal division algebras
of degree eight},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {1},
YEAR = {1933},
PAGES = {41},
DOI = {10.1090/S0002-9904-1933-05540-4},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{39}:4 (1933).
JFM:59.0168.15.},
ISSN = {0002-9904},
}
A. A. Albert :
“Cyclic fields of degree eight ,”
Bull. Am. Math. Soc.
39 : 1
(1933 ),
pp. 41 .
Abstract only; paper in Ann. Math. 35 :4 (1933) .
JFM
59.0168.16
article
BibTeX
@article {key59.0168.16j,
AUTHOR = {Albert, A. A.},
TITLE = {Cyclic fields of degree eight},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {1},
YEAR = {1933},
PAGES = {41},
DOI = {10.1090/S0002-9904-1933-05540-4},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{35}:4 (1933). JFM:59.0168.16.},
ISSN = {0002-9904},
}
A. A. Albert :
“A note on the equivalence of algebras of degree two ,”
Bull. Am. Math. Soc.
39 : 3
(1933 ),
pp. 198–199 .
Abstract only; paper in Bull. Am. Math. Soc. 39 :4 (1933) .
JFM
59.0168.17
article
BibTeX
@article {key59.0168.17j,
AUTHOR = {Albert, A. A.},
TITLE = {A note on the equivalence of algebras
of degree two},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {3},
YEAR = {1933},
PAGES = {198--199},
DOI = {10.1090/S0002-9904-1933-05581-7},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{39}:4 (1933).
JFM:59.0168.17.},
ISSN = {0002-9904},
}
A. A. Albert :
“Normal division algebras over algebraic number fields not of finite degree ,”
Bull. Am. Math. Soc.
39 : 9
(1933 ),
pp. 667 .
Abstract only; paper in Bull. Am. Math. Soc. 39 :10 (1933) .
JFM
59.0168.19
article
BibTeX
@article {key59.0168.19j,
AUTHOR = {Albert, A. A.},
TITLE = {Normal division algebras over algebraic
number fields not of finite degree},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {9},
YEAR = {1933},
PAGES = {667},
DOI = {10.1090/S0002-9904-1933-05718-X},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{39}:10 (1933).
JFM:59.0168.19.},
ISSN = {0002-9904},
}
A. A. Albert :
“Cyclic fields of degree \( p^n \) over \( F \) of characteristic \( p \) ,”
Bull. Am. Math. Soc.
40 : 8
(1934 ),
pp. 625–631 .
An abstract was published in Bull. Am. Math. Soc. 40 :3 (1934) .
MR
1562919
Zbl
0010.00402
article
Abstract
BibTeX
The theory of cyclic fields is a most interesting chapter in the study of the algebraic extensions of an abstract field \( F \) . When \( F \) is a modular field of characteristic \( p \) , a prime, particular attention is focussed on the case of cyclic fields \( Z \) of degree \( p^n \) over \( F \) . Such fields of degree \( p \) , \( p^2 \) were determined by E. Artin and O. Schreier [1926–1927].
In the present paper I shall give a determination of all cyclic fields \( Z \) of degree \( p^n \) over \( F \) of characteristic \( p \) .
@article {key1562919m,
AUTHOR = {Albert, A. A.},
TITLE = {Cyclic fields of degree \$p^n\$ over \$F\$
of characteristic \$p\$},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {8},
YEAR = {1934},
PAGES = {625--631},
DOI = {10.1090/S0002-9904-1934-05930-5},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{40}:3 (1934).
MR:1562919. Zbl:0010.00402.},
ISSN = {0002-9904},
}
A. A. Albert :
“Normal division algebras over a modular field ,”
Trans. Am. Math. Soc.
36 : 2
(1934 ),
pp. 388–394 .
An abstract was published in Bull. Am. Math. Soc. 39 :11 (1933) .
MR
1501750
JFM
60.0105.02
Zbl
0009.19502
article
Abstract
BibTeX
An infinite field \( F \) is called perfect if either \( F \) is non-modular or every quantity of \( F \) has the form \( \beta^p \) where \( p \) is the characteristic of \( F \) and \( \beta \) is in \( F \) . In any consideration of normal division algebras \( D \) over \( F \) the property that \( F \) is perfect is used only when we consider quantities of \( D \) and the minimum equations of these quantities. But if the degree \( n \) of \( D \) is not divisible by the characteristic \( p \) of \( F \) , then the assumption that \( F \) is perfect evidently has no value and is a needless extremely strong restriction on \( F \) .
In most of the papers on the structure of normal division algebras written recently in Germany, the assumption has been that \( F \) is perfect. But I shall prove here that if \( F \) is perfect of characteristic \( p \) , then \( n \) is not divisible by \( p \) . Hence it is now necessary to consider algebras of degree \( p^e \) over \( F \) of characteristic \( p \) , where \( F \) is not perfect .
I shall give here a brief discussion of the validity of the major results on algebras over non-modular fields when \( F \) is assumed to be merely any infinite field . Moreover, I shall determine all normal division algebras of degree two over \( F \) of characteristic two, of degree three over \( F \) of characteristic three.
@article {key1501750m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Normal division algebras over a modular
field},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {2},
YEAR = {1934},
PAGES = {388--394},
DOI = {10.2307/1989845},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:11 (1933).
MR:1501750. Zbl:0009.19502. JFM:60.0105.02.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“A solution of the principal problem in the theory of Riemann matrices ,”
Ann. Math. (2)
35 : 3
(July 1934 ),
pp. 500–515 .
An abstract was published in Bull. Am. Math. Soc. 40 :3 .
MR
1503176
Zbl
0010.00401
article
Abstract
BibTeX
The principal problem in the theory of Riemann matrices is that of determining the multiplication algebra \( D \) of any pure Riemann matrix \( \omega \) . This problem is of great importance in the transcendental theory of algebraic geometry, and its solution provides a solution of many related algebraic geometric questions from which it arose.
Algebra \( D \) is a normal division algebra of degree \( n \) (order \( n^2 \) ) over its centrum \( K \) . The centrum \( K \) is an algebraic field \( R(\rho) \) of all rational functions with rational coefficients of an abstract root \( \rho \) of an irreducible rational equation \( f(r) = 0 \) . We call \( \omega \) a Riemann matrix of the first or second kind according as \( f(r) = 0 \) does or does not have all real roots.
If \( \omega \) is of the first kind, then [Albert 1932] \( n=1,2 \) ; I have determined [1934] the resulting algebras \( D \) , and have proved [1934] that there exist pure Riemann matrices \( \omega \) with any one of the so determined algebras \( D \) as mutiplication algebra. There remains the case of matrices \( \omega \) of the second kind.
The remaining more difficult problem will be solved in the present paper. I shall first define a type of algebra \( \mathfrak{A} \) , shall prove the existence of Riemann matrices \( \omega \) with \( \mathfrak{A} \) as multiplication algebra, and shall finally show that the multiplication algebra \( D \) of any pure Riemann matrix \( \omega \) of the second kind is an algebra \( \mathfrak{A} \) .
@article {key1503176m,
AUTHOR = {Albert, A. Adrian},
TITLE = {A solution of the principal problem
in the theory of {R}iemann matrices},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {35},
NUMBER = {3},
MONTH = {July},
YEAR = {1934},
PAGES = {500--515},
DOI = {10.2307/1968747},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{40}:3. MR:1503176.
Zbl:0010.00401.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“Normal division algebras of degree 4 over \( F \) of characteristic 2 ,”
Am. J. Math.
56 : 1–4
(1934 ),
pp. 75–86 .
MR
1507931
JFM
60.0105.01
Zbl
0008.24202
article
Abstract
BibTeX
I have determined [1932a] all normal division algebras of degree 4 over any non-modular field \( F \) and it is evident that the determination is valid when \( F \) is any infinite modular field of characteristic \( p\neq 2 \) . There remains the case \( p=2 \) .
In the non-modular case there are but two types of algebras, the cyclic algebras and a second type containing algebras which may or may not be cyclic. I have proved [1932b; 1933] the existence of both primary and non-primary non-cyclic algebras over a non-modular \( F \) .
In the present paper I shall assume that \( F \) is any infinite field of characteristic \( p=2 \) and shall determine all normal division algebras \( D \) of degree 4 (order 16) over \( F \) . As in the non-modular case the above two types of algebras appear. However I shall prove that every non-primary \( D \) is cyclic. I shall also prove that a necessary and sufficient condition that \( D \) be cyclic is that \( D \) contain a quantity \( t \) not in \( F \) such that \( t^2 \) is in \( F \) .
Finally I shall give a construction of the non-cyclic type of algebra \( D \) and shall prove that \( D \) is a non-cyclic primary normal division algebra if and only if a certain quadratic form in nine variables (and with coefficients determined by the multiplication table of \( D \) ) is not a zero form.
@article {key1507931m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Normal division algebras of degree 4
over \$F\$ of characteristic 2},
JOURNAL = {Am. J. Math.},
FJOURNAL = {American Journal of Mathematics},
VOLUME = {56},
NUMBER = {1--4},
YEAR = {1934},
PAGES = {75--86},
DOI = {10.2307/2370915},
NOTE = {MR:1507931. Zbl:0008.24202. JFM:60.0105.01.},
ISSN = {0002-9327},
CODEN = {AJMAAN},
}
A. A. Albert :
“Integral domains of rational generalized quaternion algebras ,”
Bull. Am. Math. Soc.
40 : 2
(1934 ),
pp. 164–176 .
An abstract was published in Bull. Am. Math. Soc. 39 :7 (1933) .
MR
1562813
Zbl
0008.29301
article
Abstract
BibTeX
We shall consider generalized quaternion algebras
\[ Q = (1,i,j,ij),\quad ji = -ij,\quad i^2 = \alpha,\quad j^2 = \beta, \]
over the field \( R \) of all rational numbers.
@article {key1562813m,
AUTHOR = {Albert, A. A.},
TITLE = {Integral domains of rational generalized
quaternion algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {2},
YEAR = {1934},
PAGES = {164--176},
DOI = {10.1090/S0002-9904-1934-05828-2},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:7 (1933).
MR:1562813. Zbl:0008.29301.},
ISSN = {0002-9904},
}
A. A. Albert :
“On normal Kummer fields over a non-modular field ,”
Trans. Am. Math. Soc.
36 : 4
(1934 ),
pp. 885–892 .
MR
1501774
JFM
60.0915.03
Zbl
0010.14902
article
Abstract
BibTeX
Let \( F \) be any non-modular field, \( p \) an odd prime, \( \zeta \neq 1 \) a \( p \) th root of unity. Suppose that \( \mu \) in \( F(\zeta) \) is not the \( p- \) th power of any quantity of \( F(\zeta) \) so that the equation \( y^p=\mu \) , is irreducible in \( F(\zeta) \) . Then the field \( F(y,\zeta) \) is called a Kummer field over \( F \) .
In the present paper we shall give a formal construction of all normal Kummer fields over \( F \) . This is equivalent to a construction of all fields \( F(x) \) of degree \( p \) over \( F \) such that \( F(x,\zeta) \) is cyclic of degree \( p \) over \( F(\zeta) \) . In particular we provide a construction of all cyclic fields of degree \( p \) over \( F \) .
We shall also apply the cyclic case to prove that a normal division algebra \( D \) of degree \( p \) over \( F \) is cyclic if and only if \( D \) contains a quantity \( y \) not in \( F \) such that \( y^p=\gamma \) in \( F \) .
@article {key1501774m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On normal {K}ummer fields over a non-modular
field},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {36},
NUMBER = {4},
YEAR = {1934},
PAGES = {885--892},
DOI = {10.2307/1989831},
NOTE = {MR:1501774. Zbl:0010.14902. JFM:60.0915.03.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“On certain imprimitive fields of degree \( p^2 \) over \( P \) of characteristic \( p \) ,”
Ann. Math. (2)
35 : 2
(April 1934 ),
pp. 211–219 .
An abstract was published in Bull. Am. Math. Soc. 39 :11 (1933) .
MR
1503156
JFM
60.0915.02
Zbl
0009.24302
article
Abstract
BibTeX
E. Artin and O. Schreier have determined all cyclic fields of degree \( p \) , \( p^2 \) over a field \( P \) of characteristic \( p \) and have obtained very beautiful results [Artin and Schreier 1927]. Their latter problem on fields of degree \( p^2 \) is but a part of the more general problem of determining all imprimitive fields \( P(x) > P(u) > P \) where \( P(x) \) is cyclic of degree \( p \) over \( P(u) \) which is itself cyclic of degree \( p \) over \( P \) .
In the present paper I apply the Artin–Schreier results to solve this more general problem. In case \( p=2 \) more explicit results are obtainable and this application is also made here.
@article {key1503156m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On certain imprimitive fields of degree
\$p^2\$ over \$P\$ of characteristic \$p\$},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {35},
NUMBER = {2},
MONTH = {April},
YEAR = {1934},
PAGES = {211--219},
DOI = {10.2307/1968426},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{39}:11 (1933).
MR:1503156. Zbl:0009.24302. JFM:60.0915.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“The principal matrices of a Riemann matrix ,”
Bull. Am. Math. Soc.
40 : 12
(1934 ),
pp. 843–846 .
An abstract was published in Bull. Am. Math. Soc. 40 :9 (1934) .
MR
1562985
JFM
60.0908.01
Zbl
0010.29202
article
Abstract
BibTeX
A matrix \( \omega \) with \( p \) rows and \( 2p \) columns of complex elements is called a Riemann matrix if there exists a rational \( 2p \) -rowed skew-symmetric matrix \( C \) such that
\[ \omega C\omega^{\prime} = 0,\qquad \pi = i\omega C\overline{\omega}^{\prime} \]
is positive definite. The matrix \( C \) is called a principal matrix of \( \omega \) and it is important in algebraic geometry to know what are all principal matrices of of \( \omega \) in terms of a given one . In the present note I shall solve this problem.
@article {key1562985m,
AUTHOR = {Albert, A. A.},
TITLE = {The principal matrices of a {R}iemann
matrix},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {12},
YEAR = {1934},
PAGES = {843--846},
DOI = {10.1090/S0002-9904-1934-05980-9},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{40}:9 (1934).
MR:1562985. Zbl:0010.29202. JFM:60.0908.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“On a certain algebra of quantum mechanics ,”
Ann. Math. (2)
35 : 1
(January 1934 ),
pp. 65–73 .
MR
1503142
JFM
60.0902.03
Zbl
0008.42104
article
Abstract
BibTeX
P. Jordan, J. von Neumann, and E. Wigner [1934] have discussed certain linear real non-associative algebras of importance in quantum mechanics. Their algebras \( \mathfrak{M} \) satisfy the ordinary postulates for addition, the commutative law for multiplication, and the distributive law, but they are non-associative.
In the paper quoted above it is shown that, with a single exception, every algebra satisfying the above postulates is equivalent to an algebra \( \mathfrak{M} \) whose elements are ordinary real matrices \( x, y,\dots \) with products \( xy \) in \( \mathfrak{M} \) defined by quasi-multiplication,
\[ xy = \tfrac{1}{2}(x\cdot y + y\cdot x), \]
where \( x\cdot y \) is the ordinary matrix product. This single exception is the algebra \( \mathfrak{M}_3^8 \) of all three rowed Hermitian matrices with elements in the real non-associative algebra \( C \) of Cayley numbers.
The algebras obtained by quasi-multiplication of real matrices were considered in earlier papers so that, as stated by the above authors, this seemingly exceptional case, if proved really exceptional, is the only algebra of the above type which could lead to any new form of quantum mechanics.
In the present paper I shall prove that \( \mathfrak{M}_3^8 \) is a new algebra and that it is not equivalent to any algebra obtained by quasi-multiplication of real matrices. Moreover, I shall show that the relation
\[ x(yx^2) = (xy)x^2 \]
is satisfied by \( \mathfrak{M}_3^8 \) .
@article {key1503142m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On a certain algebra of quantum mechanics},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {35},
NUMBER = {1},
MONTH = {January},
YEAR = {1934},
PAGES = {65--73},
DOI = {10.2307/1968118},
NOTE = {MR:1503142. Zbl:0008.42104. JFM:60.0902.03.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“On the construction of Riemann matrices. I ,”
Ann. Math. (2)
35 : 1
(January 1934 ),
pp. 1–28 .
MR
1503140
JFM
60.0908.02
Zbl
0010.00304
article
BibTeX
@article {key1503140m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On the construction of {R}iemann matrices.
{I}},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {35},
NUMBER = {1},
MONTH = {January},
YEAR = {1934},
PAGES = {1--28},
DOI = {10.2307/1968116},
NOTE = {MR:1503140. Zbl:0010.00304. JFM:60.0908.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“Involutorial simple algebras and real Riemann matrices ,”
Proc. Natl. Acad. Sci. U.S.A.
20 : 12
(1934 ),
pp. 676–681 .
An abstract was published in Bull. Am. Math. Soc. 40 :11 (1934) . See also Ann. Math. (2) 36 :4 (1935) .
JFM
60.0909.01
Zbl
0010.29203
article
Abstract
BibTeX
A simple algebra \( A \) over \( F \) is said to be \( J \) -involutorial if there is a self correspondence \( J \) of \( A \) such that
\[ (a+b)^J= a^J+b^J, \quad (ab)^J = b^J a^J, \quad (a^J)^J = a, \quad \lambda^J = \lambda \]
for every \( a \) and \( b \) of \( A \) and \( \lambda \) of \( F \) . The structure problem for \( J \) -involutorial simple algebras is closely connected with the study of the multiplication algebras of real Riemann matrices. The author has completed a study of both of these problems and also has shown how closely related they are to Weyl’s recent generalization of Riemann matrices. A complete reduction of any impure real Riemann matrix to pure components has also been obtained.
@article {key0010.29203z,
AUTHOR = {Albert, A. A.},
TITLE = {Involutorial simple algebras and real
{R}iemann matrices},
JOURNAL = {Proc. Natl. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {20},
NUMBER = {12},
YEAR = {1934},
PAGES = {676--681},
DOI = {10.1073/pnas.20.12.676},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{40}:11 (1934).
See also \textit{Ann. Math.} (2) \textbf{36}:4
(1935). Zbl:0010.29203. JFM:60.0909.01.},
ISSN = {0027-8424},
}
A. A. Albert :
“Cyclic fields of degree \( p^n \) over \( F \) of characteristic \( p \) ,”
Bull. Am. Math. Soc.
40 : 3
(1934 ),
pp. 218 .
Abstract only; paper in Bull. Am. Math. Soc. 40 :8 (1934) .
JFM
60.0113.22
article
BibTeX
@article {key60.0113.22j,
AUTHOR = {Albert, A. A.},
TITLE = {Cyclic fields of degree \$p^n\$ over \$F\$
of characteristic \$p\$},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {3},
YEAR = {1934},
PAGES = {218},
DOI = {10.1090/S0002-9904-1934-05818-X},
NOTE = {Abstract only; paper in \textit{Bull.
Am. Math. Soc.} \textbf{40}:8 (1934).
JFM:60.0113.22.},
ISSN = {0002-9904},
}
A. A. Albert :
“The principal matrices of a Riemann matrix ,”
Bull. Am. Math. Soc.
40 : 9
(1934 ),
pp. 652 .
Abstract only; article in Bull. Am. Math. Soc. 40 :12 (1934) .
JFM
60.0059.05
article
BibTeX
@article {key60.0059.05j,
AUTHOR = {Albert, A. A.},
TITLE = {The principal matrices of a Riemann
matrix},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {9},
YEAR = {1934},
PAGES = {652},
DOI = {10.1090/S0002-9904-1934-05918-4},
NOTE = {Abstract only; article in \textit{Bull.
Am. Math. Soc.} \textbf{40}:12 (1934).
JFM:60.0059.05.},
ISSN = {0002-9904},
}
A. A. Albert :
“A solution of the principal problem in the theory of Riemann matrices ,”
Bull. Am. Math. Soc.
40 : 3
(1934 ),
pp. 217 .
Abstract only; paper in Ann. Math. 35 :3 (1934) .
JFM
60.0916.11
article
BibTeX
@article {key60.0916.11j,
AUTHOR = {Albert, A. A.},
TITLE = {A solution of the principal problem
in the theory of {R}iemann matrices},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {3},
YEAR = {1934},
PAGES = {217},
DOI = {10.1090/S0002-9904-1934-05818-X},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{35}:3 (1934). JFM:60.0916.11.},
ISSN = {0002-9904},
}
A. A. Albert :
“Involutorial simple algebras and real Riemann matrices ,”
Bull. Am. Math. Soc.
40
(1934 ),
pp. 808 .
Abstract only; paper in Proc. Natl. Acad. Sci. U.S.A. 20 :12 (1934) .
JFM
60.0916.10
article
BibTeX
@article {key60.0916.10j,
AUTHOR = {Albert, A. A.},
TITLE = {Involutorial simple algebras and real
{R}iemann matrices},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {40},
YEAR = {1934},
PAGES = {808},
DOI = {10.1090/S0002-9904-1934-05986-X},
NOTE = {Abstract only; paper in \textit{Proc.
Natl. Acad. Sci. U.S.A.} \textbf{20}:12
(1934). JFM:60.0916.10.},
ISSN = {0002-9904},
}
A. A. Albert :
“On the construction of Riemann matrices. II ,”
Ann. Math. (2)
36 : 2
(April 1935 ),
pp. 376–394 .
MR
1503230
JFM
61.1037.02
Zbl
0011.38904
article
BibTeX
@article {key1503230m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On the construction of {R}iemann matrices.
{II}},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {36},
NUMBER = {2},
MONTH = {April},
YEAR = {1935},
PAGES = {376--394},
DOI = {10.2307/1968578},
NOTE = {MR:1503230. Zbl:0011.38904. JFM:61.1037.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“A note on the Poincaré theorem on impure Riemann matrices ,”
Ann. Math. (2)
36 : 1
(January 1935 ),
pp. 151–156 .
MR
1503214
JFM
61.0124.01
Zbl
0011.00603
article
Abstract
BibTeX
A \( p \) by \( 2p \) complex matrix \( \omega \) is a Riemann matrix if there exists a rational \( 2p \) -rowed skew-symmetric matrix \( C \) such that \( \omega C\omega^{\prime} = 0 \) , \( i\omega C\overline{\omega}^{\prime} \) is positive definite. If \( \alpha \) is \( p \) -rowed complex and non-singular, \( A \) is \( 2p \) -rowed rational and non-singular, then \( \alpha\omega A \) and \( \omega \) are said to be isomorphic.
The period matrix of the abelian integrals of the first kind on a Riemann surface is a Riemann matrix. It was in this connection that Poincar/’e proved that if \( \omega \) is impure, that is \( \omega \) is isomorphic to
\[ \left( \begin{array}{cc} \omega_1 & 0\\ \omega_3 & \omega_2 \end{array} \right) ,\]
where \( \omega_1 \) is a Riemann matrix, then \( \omega \) is also isomorphic to
\[ \left( \begin{array}{cc} \omega_1 & 0\\ 0 & \omega_2 \end{array} \right) \]
where \( \omega_2 \) is also a Riemann matrix.
The above theorem was generalized to the case where \( \omega \) is any Riemann matrix by G. Scorza. Scorza used a rather complicated projective geometric method and his proof (as well as all previous proofs) is not very simple. I shall give here an elementary matrix proof of the above theorem and the later Scorza reduction of any impure Riemann matrix to its pure components.
@article {key1503214m,
AUTHOR = {Albert, A. Adrian},
TITLE = {A note on the {P}oincar\'e theorem on
impure {R}iemann matrices},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {36},
NUMBER = {1},
MONTH = {January},
YEAR = {1935},
PAGES = {151--156},
DOI = {10.2307/1968670},
NOTE = {MR:1503214. Zbl:0011.00603. JFM:61.0124.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“On cyclic fields ,”
Trans. Am. Math. Soc.
37 : 3
(1935 ),
pp. 454–462 .
MR
1501797
JFM
61.0124.02
Zbl
0011.29005
article
Abstract
BibTeX
The most interesting algebraic extensions of an arbitrary field \( F \) are the cyclic extension fields \( Z \) of degree \( n \) over \( F \) . I have recently given constructions of such fields for the case \( n = p \) [1934a], a prime, when the characteristic of \( F \) is not \( p \) , and for the case \( n = p^e \) [1934b] when the characteristic of \( F \) is \( p \) . Moreover it is well known that when \( F \) contains all the \( n \) th roots of unity then \( Z = F(x) \) , \( x^n = \alpha \) in \( F \) .
The last result above does not provide a construction of all cyclic fields \( Z \) over \( F \) since in general \( F \) does not contain these \( n \) th roots. Moreover if we adjoin these roots to \( F \) and so extend \( F \) to a field \( K \) the composite \( (Z,K) \) over \( K \) may not have degree \( n \) . Finally even if \( (Z,K) \) over \( K \) does have degree \( n \) then it is necessary to give conditions that a given field \( K(x) \) , \( x^n=\alpha \) in \( F \) , shall have the form \( (Z,K) \) with \( Z \) cyclic over \( F \) . This has not been done and is certainly not as simple as the considerations I shall make here.
It is well known that if \( n = p_1^{e_1}\cdots p_t^{e_t} \) with \( p_i \) distinct primes, then \( Z \) is the direct product
\[ Z = Z_1 \times \cdots \times Z_t \]
where \( Z_i \) is cyclic of degree \( p \) over \( F \) . Hence it suffices to consider the case \( n = p^e \) , \( p \) a prime. I have already done so [Albert 1934b] for the case where \( F \) has characteristic \( p \) . In the present paper I shall make analogous considerations for the case where \( F \) has characteristic not \( p \) by first studying the case where \( F \) contains a primitive \( p \) th root of unity \( \zeta \) and later giving complete conditions for the case where \( F \) does not contain \( \zeta \) .
@article {key1501797m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On cyclic fields},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {37},
NUMBER = {3},
YEAR = {1935},
PAGES = {454--462},
DOI = {10.2307/1989720},
NOTE = {MR:1501797. Zbl:0011.29005. JFM:61.0124.02.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“Involutorial simple algebras and real Riemann matrices ,”
Ann. Math. (2)
36 : 4
(October 1935 ),
pp. 886–964 .
See also Proc. Natl. Acad. Sci. U.S.A. 20 :12 (1934) .
MR
1503260
JFM
61.1038.01
Zbl
0012.39102
article
Abstract
BibTeX
Any algebraic theory depends in part on the properties of its reference field \( \mathfrak{K} \) . In particular it is generally desirable to know whether or not the Hilbert Irreducibility theorem holds in \( \mathfrak{K} \) .
W. Franz studied [1931] fields with this question in mind and proved that \( \mathfrak{K} \) is a Hilbert Irreducibility field if it is a separable algebraic extension of finite degree over a Hilbert Irreducibility field \( \mathfrak{F} \) . This is however insufficient for the theory of algebras over a modular field since the field \( \mathfrak{K} \) may be inseparable over \( \mathfrak{F} \) .
We shall treat this latter case here and shall show that any algebraic extension \( \mathfrak{K} \) of finite degree over a Hilbert Irreducibility field \( \mathfrak{F} \) is a Hilbert irreducibility field. Moreover this result will be a sufficiently good tool for the researches of later chapters.
@article {key1503260m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Involutorial simple algebras and real
{R}iemann matrices},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {36},
NUMBER = {4},
MONTH = {October},
YEAR = {1935},
PAGES = {886--964},
DOI = {10.2307/1968595},
NOTE = {See also \textit{Proc. Natl. Acad. Sci.
U.S.A.} \textbf{20}:12 (1934). MR:1503260.
Zbl:0012.39102. JFM:61.1038.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“Simple algebras of degree \( p^e \) over a centrum of characteristic \( p \) ,”
Bull. Am. Math. Soc.
41 : 7
(1935 ),
pp. 489 .
Abstract only; paper in Trans. Am. Math. Soc. 40 :1 (1936) .
JFM
61.0127.09
article
BibTeX
@article {key61.0127.09j,
AUTHOR = {Albert, A. A.},
TITLE = {Simple algebras of degree \$p^e\$ over
a centrum of characteristic \$p\$},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {41},
NUMBER = {7},
YEAR = {1935},
PAGES = {489},
DOI = {10.1090/S0002-9904-1935-06131-2},
NOTE = {Abstract only; paper in \textit{Trans.
Am. Math. Soc.} \textbf{40}:1 (1936).
JFM:61.0127.09.},
ISSN = {0002-9904},
}
A. A. Albert :
“Normal division algebras of degree \( p^e \) over \( F \) of characteristic \( p \) ,”
Trans. Am. Math. Soc.
39 : 1
(January 1936 ),
pp. 183–188 .
MR
1501840
JFM
62.0101.01
Zbl
0013.10202
article
Abstract
BibTeX
In a recent paper [1934] I proved that a normal division algebra \( D \) of degree \( p \) , a prime, over a field \( F \) of characteristic not \( p \) , is cyclic if and only if \( D \) contains a sub-field \( F(y) \) , \( y^p = \gamma \) in \( F \) . This result evidently leads to the conjecture that any normal division algebra \( D \) of degree \( n \) over \( F \) is cyclic over \( F \) if and only if \( D \) contains a maximal sub-field, \( F(y) \) , \( y^n = \gamma \) in \( F \) .
The conjectured criterion given above would be of fundamental importance for the theory of the structure of normal division algebras. Without loss of generality we may assume that \( n=p^e \) , \( p \) a prime, and the theory then gives rise to two distinct cases according as \( F \) does or does not have characteristic \( p \) . We shall consider the former case here and give a brief simple proof of the criterion.
@article {key1501840m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Normal division algebras of degree \$p^e\$
over \$F\$ of characteristic \$p\$},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {39},
NUMBER = {1},
MONTH = {January},
YEAR = {1936},
PAGES = {183--188},
DOI = {10.2307/1989650},
NOTE = {MR:1501840. Zbl:0013.10202. JFM:62.0101.01.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“Simple algebras of degree \( p^e \) over a centrum of characteristic \( p \) ,”
Trans. Am. Math. Soc.
40 : 1
(July 1936 ),
pp. 112–126 .
An abstract was published in Bull. Am. Math. Soc. 41 :7 (1935) .
MR
1501866
JFM
62.0101.02
Zbl
0014.29102
article
Abstract
BibTeX
The study of normal simple algebras \( A \) over a field \( F \) has been reduced to the case where the degree of \( A \) is a power of a prime \( p \) . The theory then splits sharply into two cases distinguished by the hypothesis that the characteristic of \( F \) is or is not \( p \) . We shall restrict our attention to the former case.
It is well known that every normal simple algebra \( A \) over \( F \) is similar to a crossed product \( B \) . But this result is of little aid in a study of \( A \) , since in fact the degree of \( B \) is in general not a power of \( p \) . We shall prove here, however, that in our case every \( A \) is similar to a cyclic algebra whose degree is a power of \( p \) .
If \( K \) is obtained from \( F \) by adjoining the \( p^e \) th roots of quantities of \( F \) to \( F \) , for fixed \( e \) , then \( K \) is said to have exponent \( e \) over \( F \) . We shall show that the exponent of an algebra \( A \) is \( p^e \) where \( e \) is the exponent of the above \( K \) of least exponent, which splits \( A \) . Moreover \( A \) has exponent \( p^e \) only if \( A \) is similar to a direct product of cyclic division algebras \( D_i \) whose exponents and degrees are equal to \( p^{e_i}\leq p^e \) , \( D_1 \) of degree \( p^e \) .
@article {key1501866m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Simple algebras of degree \$p^e\$ over
a centrum of characteristic \$p\$},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {40},
NUMBER = {1},
MONTH = {July},
YEAR = {1936},
PAGES = {112--126},
DOI = {10.2307/1989665},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{41}:7 (1935).
MR:1501866. Zbl:0014.29102. JFM:62.0101.02.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“Normalized integral bases of algebraic number fields, I ,”
Bull. Am. Math. Soc.
42 : 11
(1936 ),
pp. 811 .
Abstract only; paper in Ann. Math. 38 :4 (1937) .
JFM
62.0172.06
article
BibTeX
@article {key62.0172.06j,
AUTHOR = {Albert, A. A.},
TITLE = {Normalized integral bases of algebraic
number fields, {I}},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {42},
NUMBER = {11},
YEAR = {1936},
PAGES = {811},
DOI = {10.1090/S0002-9904-1936-06454-2},
NOTE = {Abstract only; paper in \textit{Ann.
Math.} \textbf{38}:4 (1937). JFM:62.0172.06.},
ISSN = {0002-9904},
}
A. A. Albert :
“\( p \) -algebras over a field generated by one indeterminate ,”
Bull. Am. Math. Soc.
43 : 10
(1937 ),
pp. 733–736 .
MR
1563627
JFM
63.0875.01
Zbl
0017.24501
article
Abstract
BibTeX
The structure of all division algebras over the simplest type of non-modular field, the field of all rational numbers, has been determined [Hasse and Albert 1932]. The correspondingly simplest type of infinite modular field is the simple transcendental extension \( K = F(x) \) of a finite field \( F \) . Every division algebra \( D \) over such a \( K \) is a normal division algebra of degree \( n \) over a centrum \( G \) which is algebraic of finite degree over \( K \) . It is well known that the problem of determining the structure of \( D \) is reducible to the case where \( n \) is a power of a prime \( p \) . When \( p \) is the characteristic of \( F \) the algebra \( D \) is called a \( p \) -algebra and we shall solve the problem in this case. Our results will be valid if we replace the finite field \( F \) by any perfect field of characteristic \( p \) .
The theorem we shall obtain is remarkable not merely because of the character of the result thus derived but also because of the extremely elementary nature of the proof. By using a simple property of the field \( G \) described above we shall show that every \( p \) -algebra with centrum \( G \) is cyclic and of exponent equal to its degree. Moreover this result is due to the unusual fact that all cyclic algebras over \( G \) of the same degree \( p^e \) have a common pure inseparable splitting field.
@article {key1563627m,
AUTHOR = {Albert, A. A.},
TITLE = {\$p\$-algebras over a field generated
by one indeterminate},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {43},
NUMBER = {10},
YEAR = {1937},
PAGES = {733--736},
DOI = {10.1090/S0002-9904-1937-06636-5},
NOTE = {MR:1563627. Zbl:0017.24501. JFM:63.0875.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“Normalized integral bases of algebraic number fields. I ,”
Ann. Math. (2)
38 : 4
(October 1937 ),
pp. 923–957 .
An abstract was published in Bull. Am. Math. Soc. 42 :11 (1936) .
MR
1503382
JFM
63.0910.01
Zbl
0018.05102
article
Abstract
BibTeX
Every algebraic number field \( \mathfrak{F} \) of degree \( n \) over the rational number field is defined by a root \( \theta \) of an irreducible rational equation \( f(x) = 0 \) of degree \( n \) . One of the most interesting problems in the theory of such fields is that of finding explicit formulae for the quantities of a basis of the integers of \( \mathfrak{F} \) in terms of \( \theta \) and the coefficients of \( f(x) \) . This problem has had no general solution and has not been completely solved even for the case \( n=4 \) .
Some simplifications in the above formulae may be obtained by choosing \( \theta \) to be an algebraic integer and such that \( a\theta \) is an algebraic integer for rational \( a \) if and only if \( a \) is integral. These are partial normalizations on \( \theta \) . Additional simplifications of the formulae are obtained when we choose \( \theta \) to have zero trace, that is the coefficient of \( x^{n-1} \) in \( f(x) \) to be zero.
In the present paper we shall obtain simplifications by making further normalizations on \( \theta \) . We shall in fact show that every \( \mathfrak{F} \) of degree \( n > 2 \) is generated by a quantity \( \theta \) such that in addition to the above properties the first two elements of an integral basis of \( \mathfrak{F} \) are
\[ 1,\quad \theta \]
This result will be completed here by our giving necessary and sufficient conditions on \( f(x) \) that \( \theta \) have the desired properties.
@article {key1503382m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Normalized integral bases of algebraic
number fields. {I}},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {38},
NUMBER = {4},
MONTH = {October},
YEAR = {1937},
PAGES = {923--957},
DOI = {10.2307/1968847},
NOTE = {An abstract was published in \textit{Bull.
Am. Math. Soc.} \textbf{42}:11 (1936).
MR:1503382. Zbl:0018.05102. JFM:63.0910.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“A note on matrices defining total real fields ,”
Bull. Am. Math. Soc.
43 : 4
(1937 ),
pp. 242–244 .
MR
1563515
JFM
63.0142.05
Zbl
0016.15003
article
BibTeX
@article {key1563515m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on matrices defining total real
fields},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {43},
NUMBER = {4},
YEAR = {1937},
PAGES = {242--244},
DOI = {10.1090/S0002-9904-1937-06524-4},
NOTE = {MR:1563515. Zbl:0016.15003. JFM:63.0142.05.},
ISSN = {0002-9904},
}
A. A. Albert :
Modern higher algebra .
University of Chicago Press ,
1937 .
JFM
63.0868.01
Zbl
0017.29201
book
BibTeX
@book {key0017.29201z,
AUTHOR = {Albert, A. A.},
TITLE = {Modern higher algebra},
PUBLISHER = {University of Chicago Press},
YEAR = {1937},
PAGES = {xiv+319},
NOTE = {Zbl:0017.29201. JFM:63.0868.01.},
}
A. A. Albert :
“A note on normal division algebras of prime degree ,”
Bull. Am. Math. Soc.
44 : 10
(1938 ),
pp. 649–652 .
MR
1563842
JFM
64.0081.04
Zbl
0019.29002
article
Abstract
BibTeX
Let \( \mathfrak{D} \) be a normal division algebra of degree \( p \) over a field \( \mathfrak{K} \) of characteristic \( p \) , and let \( m \) be prime to \( p \) . Then if \( \mathfrak{D} \) has a normal splitting field \( \mathfrak{W} \) of degree \( pm \) over \( \mathfrak{K} \) , with a cyclic subfield \( \mathfrak{L} \) of degree \( m \) over \( \mathfrak{K} \) , it follows that the algebra \( \mathfrak{D} \) is a cyclic algebra.
@article {key1563842m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on normal division algebras of
prime degree},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {44},
NUMBER = {10},
YEAR = {1938},
PAGES = {649--652},
DOI = {10.1090/S0002-9904-1938-06831-0},
NOTE = {MR:1563842. Zbl:0019.29002. JFM:64.0081.04.},
ISSN = {0002-9904},
}
A. A. Albert :
“On cyclic algebras ,”
Ann. Math. (2)
39 : 3
(July 1938 ),
pp. 669–682 .
MR
1503431
JFM
64.0082.02
Zbl
0019.24601
article
BibTeX
@article {key1503431m,
AUTHOR = {Albert, A. Adrian},
TITLE = {On cyclic algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {39},
NUMBER = {3},
MONTH = {July},
YEAR = {1938},
PAGES = {669--682},
DOI = {10.2307/1968641},
NOTE = {MR:1503431. Zbl:0019.24601. JFM:64.0082.02.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
“Non-cyclic algebras with pure maximal subfields ,”
Bull. Am. Math. Soc.
44 : 8
(1938 ),
pp. 576–579 .
MR
1563796
JFM
64.0082.01
Zbl
0019.19302
article
Abstract
BibTeX
Let \( x \) , \( y \) , \( z \) be independent indeterminates over a field \( F \) of real numbers, \( K = F(x,y,z) \) . Then there exist non-cyclic normal division algebras of degree and exponent four over \( K \) , each with a subfield \( K(j) \) of degree four over \( K \) such that \( j^4 = \gamma \) in \( K \) .
@article {key1563796m,
AUTHOR = {Albert, A. A.},
TITLE = {Non-cyclic algebras with pure maximal
subfields},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {44},
NUMBER = {8},
YEAR = {1938},
PAGES = {576--579},
DOI = {10.1090/S0002-9904-1938-06814-0},
NOTE = {MR:1563796. Zbl:0019.19302. JFM:64.0082.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“Symmetric and alternate matrices in an arbitrary field. I ,”
Trans. Am. Math. Soc.
43 : 3
(May 1938 ),
pp. 386–436 .
MR
1501952
Zbl
0018.34202
article
Abstract
BibTeX
The elementary theorems of the classical treatment of symmetric and alternate matrices may be shown, without change in the proofs, to hold for matrices whose elements are in any field of characteristic not two. The proofs fail in the characteristic two case and the results cannot hold since here the concepts of symmetric and alternate matrices coincide. But it is possible to obtain a unified treatment. We shall provide this here by adding a condition to the definition of alternate matrices which is redundant except for fields of characteristic two. The proofs of the classical results will then be completed by the addition of two necessary new arguments.
@article {key1501952m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Symmetric and alternate matrices in
an arbitrary field. {I}},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {43},
NUMBER = {3},
MONTH = {May},
YEAR = {1938},
PAGES = {386--436},
DOI = {10.2307/1990068},
NOTE = {MR:1501952. Zbl:0018.34202.},
ISSN = {0002-9947},
CODEN = {TAMTAM},
}
A. A. Albert :
“A quadratic form problem in the calculus of variations ,”
Bull. Am. Math. Soc.
44 : 4
(1938 ),
pp. 250–253 .
MR
1563719
JFM
64.0515.01
Zbl
0018.24201
article
Abstract
BibTeX
The problem which we shall discuss arose in connection with sufficiency theorems in the multiple integral problem of the calculus of variations. It was proposed by Professor G. A. Bliss to his University of Chicago seminar (summer, 1937) and communicated to the author by Professor W. T. Reid. The result of the author’s investigation presented here is a very interesting theorem on real quadratic forms.
@article {key1563719m,
AUTHOR = {Albert, A. Adrian},
TITLE = {A quadratic form problem in the calculus
of variations},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {44},
NUMBER = {4},
YEAR = {1938},
PAGES = {250--253},
DOI = {10.1090/S0002-9904-1938-06730-4},
NOTE = {MR:1563719. Zbl:0018.24201. JFM:64.0515.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“The Chicago conference and seminar on algebra ,”
Bull. Am. Math. Soc.
44 : 11
(1938 ),
pp. 756–757 .
MR
1563863
article
BibTeX
@article {key1563863m,
AUTHOR = {Albert, A. A.},
TITLE = {The {C}hicago conference and seminar
on algebra},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {44},
NUMBER = {11},
YEAR = {1938},
PAGES = {756--757},
DOI = {10.1090/S0002-9904-1938-06865-6},
NOTE = {MR:1563863.},
ISSN = {0002-9904},
}
A. A. Albert :
“Quadratic null forms over a function field ,”
Ann. Math. (2)
39 : 2
(April 1938 ),
pp. 494–505 .
MR
1503420
JFM
64.0083.01
Zbl
0019.00207
article
BibTeX
@article {key1503420m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Quadratic null forms over a function
field},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {39},
NUMBER = {2},
MONTH = {April},
YEAR = {1938},
PAGES = {494--505},
DOI = {10.2307/1968799},
NOTE = {MR:1503420. Zbl:0019.00207. JFM:64.0083.01.},
ISSN = {0003-486X},
CODEN = {ANMAAH},
}
A. A. Albert :
Modern higher algebra .
Cambridge University Press ,
1938 .
Zbl
0019.14705
book
BibTeX
@book {key0019.14705z,
AUTHOR = {Albert, A. A.},
TITLE = {Modern higher algebra},
PUBLISHER = {Cambridge University Press},
YEAR = {1938},
PAGES = {xiv+319},
NOTE = {Zbl:0019.14705.},
}
A. A. Albert :
Structure of algebras .
AMS Colloquium Publications 24 .
American Mathematical Society (Providence, RI ),
1939 .
MR
0000595
Zbl
0023.19901
book
BibTeX
@book {key0000595m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Structure of algebras},
SERIES = {AMS Colloquium Publications},
NUMBER = {24},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1939},
PAGES = {xi+210},
NOTE = {MR:1,99c. Zbl:0023.19901.},
}
A. A. Albert :
“On ordered algebras ,”
Bull. Am. Math. Soc.
46
(1940 ),
pp. 521–522 .
MR
0001972
JFM
66.0114.01
Zbl
0061.05502
article
Abstract
BibTeX
@article {key0001972m,
AUTHOR = {Albert, A. A.},
TITLE = {On ordered algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {46},
YEAR = {1940},
PAGES = {521--522},
DOI = {10.1090/S0002-9904-1940-07252-0},
NOTE = {MR:1,328e. Zbl:0061.05502. JFM:66.0114.01.},
ISSN = {0002-9904},
}
A. A. Albert :
“On \( p \) -adic fields and rational division algebras ,”
Ann. Math. (2)
41 : 3
(July 1940 ),
pp. 674–693 .
MR
0002861
JFM
66.0116.01
Zbl
0024.14602
article
Abstract
BibTeX
We shall use a very simple lemma of what may be called an arithmetical nature on \( p \) -adic fields and shall give a consequent new algebraic discussion of fields \( \mathfrak{K} \) of finite degree and ramification order \( e \) prime to \( p \) over a \( p \) -adic field \( \mathfrak{F} \) . We shall construct all such fields, show that the number of such fields inequivalent over \( \mathfrak{F} \) is an explicitly determined divisor of \( e \) , and shall determine necessary and sufficient conditions that \( \mathfrak{K} \) be normal over \( \mathfrak{F} \) . We shall determine the automorphism group of \( \mathfrak{K} \) over \( \mathfrak{F} \) , and prove the rather amazing result that the existence of any abelian field of the given ramification order \( e \) over \( \mathfrak{F} \) implies that al fields with the same \( e \) are abelian over \( \mathfrak{F} \) . Finally we shall determine explicitly which abelian fields are cyclic, how many cyclic fields exist which are inequivalent over \( \mathfrak{F} \) , the direct factorization into two cyclic fields of all non-cyclic abelian fields.
@article {key0002861m,
AUTHOR = {Albert, A. A.},
TITLE = {On \$p\$-adic fields and rational division
algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {41},
NUMBER = {3},
MONTH = {July},
YEAR = {1940},
PAGES = {674--693},
DOI = {10.2307/1968740},
NOTE = {MR:2,123b. Zbl:0024.14602. JFM:66.0116.01.},
ISSN = {0003-486X},
}
A. A. Albert :
“A rule for computing the inverse of a matrix ,”
Am. Math. Monthly
48 : 3
(March 1941 ),
pp. 198–199 .
MR
0003603
JFM
67.0052.03
Zbl
0060.03301
article
BibTeX
@article {key0003603m,
AUTHOR = {Albert, A. A.},
TITLE = {A rule for computing the inverse of
a matrix},
JOURNAL = {Am. Math. Monthly},
FJOURNAL = {The American Mathematical Monthly},
VOLUME = {48},
NUMBER = {3},
MONTH = {March},
YEAR = {1941},
PAGES = {198--199},
DOI = {10.2307/2304250},
NOTE = {MR:2,243c. Zbl:0060.03301. JFM:67.0052.03.},
ISSN = {0002-9890},
}
A. A. Albert :
“Book review: The theory of group characters ,”
Bull. Am. Math. Soc.
47 : 5
(1941 ),
pp. 357–359 .
Book by Dudley E. Littlewood (Oxford University Press, 1940).
MR
1564250
article
People
BibTeX
@article {key1564250m,
AUTHOR = {Albert, A. A.},
TITLE = {Book review: {T}he theory of group characters},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {47},
NUMBER = {5},
YEAR = {1941},
PAGES = {357--359},
DOI = {10.1090/S0002-9904-1941-07444-6},
NOTE = {Book by Dudley E. Littlewood (Oxford
University Press, 1940). MR:1564250.},
ISSN = {0002-9904},
}
A. A. Albert :
Introduction to algebraic theories .
University of Chicago Press ,
1941 .
MR
0003590
JFM
67.0045.03
Zbl
0027.00601
book
BibTeX
@book {key0003590m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Introduction to algebraic theories},
PUBLISHER = {University of Chicago Press},
YEAR = {1941},
PAGES = {viii+137},
NOTE = {MR:2,241a. Zbl:0027.00601. JFM:67.0045.03.},
}
A. A. Albert :
“Division algebras over a function field ,”
Duke Math. J.
8 : 4
(1941 ),
pp. 750–762 .
MR
0006168
Zbl
0061.05503
article
Abstract
BibTeX
The most important splitting fields \( K \) of a division algebra \( D \) of degree \( m \) over its centrum \( F \) are those fields of least possible degree over \( F \) . This degree is \( m \) and it is known [Albert 1939, Theorem 4.27] also that all such fields are equivalent to subields of \( D \) of maximal degree over \( F \) . It is natural then to propose the question as to the universal existence of a constant splitting field over \( F \) of degree \( m \) over \( L \) for any \( D \) . In particular a cyclic field of this kind would provide an extremely simple generation of \( D \) .
We shall answer the question just proposed in the negative and shall prove indeed that the least degree \( n \) of a constant splitting field may be arbitrarily large. We shall prove in fact the:
Let \( x \) be an indeterminate over a finite field \( L \) , \( F = L(x) \) , \( m \) and \( n \) be positive integers. Then there exist division algebras \( D \) of degree \( m \) over \( F \) as centrum and with \( n \) as the least degree over \( L \) of a constant splitting field over \( F \) of \( D \) if and only if \( m \) divides \( n \) and every prime factor of \( n \) divides \( m \) .
@article {key0006168m,
AUTHOR = {Albert, A. A.},
TITLE = {Division algebras over a function field},
JOURNAL = {Duke Math. J.},
FJOURNAL = {Duke Mathematical Journal},
VOLUME = {8},
NUMBER = {4},
YEAR = {1941},
PAGES = {750--762},
DOI = {10.1215/S0012-7094-41-00864-5},
NOTE = {MR:3,265d. Zbl:0061.05503.},
ISSN = {0012-7094},
}
A. A. Albert :
“Quadratic forms permitting composition ,”
Ann. Math. (2)
43 : 1
(January 1942 ),
pp. 161–177 .
MR
0006140
JFM
68.0051.02
Zbl
0060.04003
article
BibTeX
@article {key0006140m,
AUTHOR = {Albert, A. A.},
TITLE = {Quadratic forms permitting composition},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {43},
NUMBER = {1},
MONTH = {January},
YEAR = {1942},
PAGES = {161--177},
DOI = {10.2307/1968887},
NOTE = {MR:3,261a. Zbl:0060.04003. JFM:68.0051.02.},
ISSN = {0003-486X},
}
A. A. Albert :
“Non-associative algebras. II: New simple algebras ,”
Ann. Math. (2)
43 : 4
(October 1942 ),
pp. 708–723 .
MR
0007748
Zbl
0061.04901
article
Abstract
BibTeX
@article {key0007748m,
AUTHOR = {Albert, A. A.},
TITLE = {Non-associative algebras. {II}: {N}ew
simple algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {43},
NUMBER = {4},
MONTH = {October},
YEAR = {1942},
PAGES = {708--723},
DOI = {10.2307/1968961},
NOTE = {MR:4,186b. Zbl:0061.04901.},
ISSN = {0003-486X},
}
A. A. Albert :
“Non-associative algebras. I: Fundamental concepts and isotopy ,”
Ann. Math. (2)
43 : 4
(October 1942 ),
pp. 685–707 .
MR
0007747
Zbl
0061.04807
article
BibTeX
@article {key0007747m,
AUTHOR = {Albert, A. A.},
TITLE = {Non-associative algebras. {I}: {F}undamental
concepts and isotopy},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {43},
NUMBER = {4},
MONTH = {October},
YEAR = {1942},
PAGES = {685--707},
DOI = {10.2307/1968960},
NOTE = {MR:4,186a. Zbl:0061.04807.},
ISSN = {0003-486X},
}
A. A. Albert :
“The radical of a non-associative algebra ,”
Bull. Am. Math. Soc.
48
(1942 ),
pp. 891–897 .
MR
0007396
Zbl
0061.05001
article
Abstract
BibTeX
Every algebra \( \mathfrak{A} \) which is homomorphic to a semi-simple algebra has an ideal \( \mathfrak{R} \) . which we shall call the radical of \( \mathfrak{A} \) , such that \( \mathfrak{A} - \mathfrak{R} \) is semi-simple, \( \mathfrak{R} \) is contained in every ideal \( \mathfrak{B} \) of \( \mathfrak{A} \) for which \( \mathfrak{A} - \mathfrak{B} \) is semi-simple.
An algebra \( \mathfrak{A} \) is homomorphic to a semi-simple algebra if and only if \( \mathfrak{A} - \mathfrak{A}\mathfrak{H} \) is not a zero algebra.
If \( \mathfrak{A} - \mathfrak{A}\mathfrak{H} \) is a zero algebra and \( \mathfrak{B} \) is an ideal of \( \mathfrak{A} \) the algebra \( \mathfrak{A} - \mathfrak{B} \) is a zero algebra if and only if \( \mathfrak{B} \) contains \( \mathfrak{A}\mathfrak{H} \) .
Let \( \mathfrak{A} \) be homomorphic to a semi-simple algebra. Then either \( \mathfrak{A} - \mathfrak{A}\mathfrak{H} \) is semi-simple and \( \mathfrak{A}\mathfrak{H} \) is the radical of \( \mathfrak{A} \) or \( \mathfrak{A} - \mathfrak{A}\mathfrak{H} \) is the direct sum of a semi-simple algebra and a zero algebra \( \mathfrak{R}_0 = \mathfrak{R} - \mathfrak{A}\mathfrak{H} \) such that \( \mathfrak{R} \) is the radical of \( \mathfrak{A} \) .
@article {key0007396m,
AUTHOR = {Albert, A. A.},
TITLE = {The radical of a non-associative algebra},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {48},
YEAR = {1942},
PAGES = {891--897},
DOI = {10.1090/S0002-9904-1942-07814-1},
NOTE = {MR:4,130b. Zbl:0061.05001.},
ISSN = {0002-9904},
}
A. A. Albert :
“An inductive proof of Descartes’ rule of signs ,”
Am. Math. Monthly
50 : 3
(March 1943 ),
pp. 178–180 .
MR
0007806
Zbl
0060.05004
article
Abstract
BibTeX
The so-called proofs of Descartes’ Rule generally given in college algebras are merely verifications of special cases. The only rigorous direct proof in the literature known to me is that of L. E. Dickson’s First Course in the Theory of Equations . This proof uses a rather complicated notation and has always seemed to me to be difficult to follow.
I have recently discovered an alteration in the proof which enables the omission of any consideration of permanences. This results in a fundamental simplication of the notation. I present it here in full detail.
@article {key0007806m,
AUTHOR = {Albert, A. A.},
TITLE = {An inductive proof of {D}escartes' rule
of signs},
JOURNAL = {Am. Math. Monthly},
FJOURNAL = {The American Mathematical Monthly},
VOLUME = {50},
NUMBER = {3},
MONTH = {March},
YEAR = {1943},
PAGES = {178--180},
DOI = {10.2307/2302399},
NOTE = {MR:4,195e. Zbl:0060.05004.},
ISSN = {0002-9890},
}
A. A. Albert :
“A suggestion for a simplified trigonometry ,”
Am. Math. Monthly
50 : 4
(1943 ),
pp. 251–253 .
MR
1525668
article
BibTeX
@article {key1525668m,
AUTHOR = {Albert, A. A.},
TITLE = {A suggestion for a simplified trigonometry},
JOURNAL = {Am. Math. Monthly},
FJOURNAL = {The American Mathematical Monthly},
VOLUME = {50},
NUMBER = {4},
YEAR = {1943},
PAGES = {251--253},
DOI = {10.2307/2303930},
NOTE = {MR:1525668.},
ISSN = {0002-9890},
CODEN = {AMMYAE},
}
A. A. Albert :
“Quasigroups. I ,”
Trans. Am. Math. Soc.
54
(1943 ),
pp. 507–519 .
MR
0009962
Zbl
0063.00039
article
Abstract
BibTeX
A theory of non-associative algebras has been developed [Jacobson 1937; Albert 1942a, 1942b] without any assumption of a substitute for the associative law, and the basic structure properties of such algebras have been shown to depend upon the possession of almost these same properties by related associative algebras.
It seems natural then to attempt to obtain an analogous treatment of quasigroups. We shall present the results here. Most of the results in the literature on quasigroups do depend upon special associativity conditions [Suschkewitsch 1929] but no assumption of such conditions is necessary for our theorems.
@article {key0009962m,
AUTHOR = {Albert, A. A.},
TITLE = {Quasigroups. {I}},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {54},
YEAR = {1943},
PAGES = {507--519},
DOI = {10.2307/1990259},
NOTE = {MR:5,229c. Zbl:0063.00039.},
ISSN = {0002-9947},
}
A. A. Albert :
“The minimum rank of a correlation matrix ,”
Proc. Nat. Acad. Sci. U. S. A.
30 : 6
(June 1944 ),
pp. 144–146 .
MR
0010351
Zbl
0063.00041
article
BibTeX
@article {key0010351m,
AUTHOR = {Albert, A. A.},
TITLE = {The minimum rank of a correlation matrix},
JOURNAL = {Proc. Nat. Acad. Sci. U. S. A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {30},
NUMBER = {6},
MONTH = {June},
YEAR = {1944},
PAGES = {144--146},
DOI = {10.1073/pnas.30.6.144},
NOTE = {MR:6,6a. Zbl:0063.00041.},
ISSN = {0027-8424},
}
A. A. Albert :
“Quasigroups. II ,”
Trans. Am. Math. Soc.
55 : 3
(May 1944 ),
pp. 401–419 .
MR
0010597
Zbl
0063.00042
article
Abstract
BibTeX
In the first part of this paper [1943] we associated every quasigroup \( \mathfrak{G} \) with the transformation group \( \mathfrak{G}_r \) generated by the right and left multiplications of \( \mathfrak{G} \) . We defined isotopy and showed that every quasigroup is isotopic to a loop, that is, a quasigroup \( \mathfrak{G} \) with identity element \( e \) . We also defined the concept of normal divisor for all loops and showed that every normal divisor \( \mathfrak{H} \) of \( \mathfrak{G} \) is equal to \( e\Gamma \) where \( \Gamma \) is a normal divisor of \( \mathfrak{G}_r \) .
The main purpose of this second part of our paper is that of presenting a proof, using the results above, of the Schreier refinement theorem and the consquent Jordan–Hölder theorem for arbitrary loops. We obtain also a number of special results, among them a construction of all loops \( \mathfrak{G} \) with a given normal divisor \( \mathfrak{H} \) and a given quotient loop \( \mathfrak{G}/\mathfrak{H} \) . We use this in the construction of all loops of order six with a subloop, necessarily a normal divisor, of order three. We classify these loops into nonisotopic classes and show also that all quasigroups of order five are isotopic to one of two nonisotopic loops.
@article {key0010597m,
AUTHOR = {Albert, A. A.},
TITLE = {Quasigroups. {II}},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {55},
NUMBER = {3},
MONTH = {May},
YEAR = {1944},
PAGES = {401--419},
DOI = {10.2307/1990300},
NOTE = {MR:6,42a. Zbl:0063.00042.},
ISSN = {0002-9947},
}
A. A. Albert :
“The matrices of factor analysis ,”
Proc. Nat. Acad. Sci. U. S. A.
30 : 4
(April 1944 ),
pp. 90–95 .
MR
0009829
Zbl
0063.00040
article
BibTeX
@article {key0009829m,
AUTHOR = {Albert, A. A.},
TITLE = {The matrices of factor analysis},
JOURNAL = {Proc. Nat. Acad. Sci. U. S. A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {30},
NUMBER = {4},
MONTH = {April},
YEAR = {1944},
PAGES = {90--95},
DOI = {10.1073/pnas.30.4.90},
NOTE = {MR:5,209f. Zbl:0063.00040.},
ISSN = {0027-8424},
}
A. A. Albert :
“Two element generation of a separable algebra ,”
Bull. Am. Math. Soc.
50
(1944 ),
pp. 786–788 .
MR
0011080
Zbl
0061.05501
article
Abstract
BibTeX
The minimum rank of an algebra \( A \) over a field \( F \) is defined to be the least number \( r = r(A) \) of elements \( x_1,\dots,x_r \) such that \( A \) is the set of all polynomials in \( x_1,\dots,x_r \) with coefficients in \( F \) . In what follows we shall assume that \( A \) is an associative algebra of finite order over an infinite field \( F \) .
It is well known that \( r(A) = 1 \) if \( A \) is a separable field over \( F \) and that \( r(A) = 2 \) if \( A \) is a total matric algebra over \( F \) . Over fourteen years ago I obtained but did not publish the result that \( r(A) = 2 \) if \( A \) is a central division algebra over \( F \) . The purpose of this note is to provide a brief proof of the generalization which states that if \( A \) is any separable algebra over \( F \) then \( r(A) = 1 \) or 2 according as \( A \) is or is not commutative.
@article {key0011080m,
AUTHOR = {Albert, A. A.},
TITLE = {Two element generation of a separable
algebra},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {50},
YEAR = {1944},
PAGES = {786--788},
DOI = {10.1090/S0002-9904-1944-08238-4},
NOTE = {MR:6,115d. Zbl:0061.05501.},
ISSN = {0002-9904},
}
A. A. Albert :
“Quasiquaternion algebras ,”
Ann. Math. (2)
45 : 4
(October 1944 ),
pp. 623–638 .
MR
0011081
Zbl
0061.05002
article
Abstract
BibTeX
We shall consider here certain algebras of order four over a general field \( \mathfrak{F} \) . They are a generalization of the “generalized quaternion” algebras of L. E. Dickson which have proved to be such an important special case in the associative theory, and speicalize to the associative case when a single parameter \( \tau = 0 \) . The algebras are not associative if and only if \( \tau \neq 0,1 \) and are central simple.
We shall show that the theory of isomorphism, automorphisms, proper subalgebras, and division algebras for these algebras is actually much simpler than in the associative case, a result quite contrary to what might have been expected. Indeed, the theory is remarkably like the theory of quadratic fields. We shall also obtain a complete study of the conditions that two of our quasiquaternion division algebras over a field of characteristic not two be isotopic.
@article {key0011081m,
AUTHOR = {Albert, A. A.},
TITLE = {Quasiquaternion algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {45},
NUMBER = {4},
MONTH = {October},
YEAR = {1944},
PAGES = {623--638},
DOI = {10.2307/1969293},
NOTE = {MR:6,115e. Zbl:0061.05002.},
ISSN = {0003-486X},
}
A. A. Albert :
“Algebras derived by non-associative matrix multiplication ,”
Am. J. Math.
66 : 1
(January 1944 ),
pp. 30–40 .
MR
0009949
Zbl
0061.05003
article
Abstract
BibTeX
There are four ways to form an \( n \) -rowed matrix whose determinant is the product of the determinants of two \( n \) -rowed matrices, and only one of these, the row by column product, is an associative product. The row by row, column by column, and column by row products determine algebras which are not associative and it has recently been suggested to the author, in conversation, that these algebras have applications to some problems of physics.
We shall study the structure of such algebras here with particular attention to those algebras obtained by the three non-associative products from associative algebras \( \mathfrak{C} \) such that \( \mathfrak{C} \) contains the transpose \( x^{\prime} \) of every \( x \) of \( \mathfrak{C} \) . We shall indeed obtain a general structure theory not merely for such algebras but for the case where \( \mathfrak{C} \) is any algebra with an involution \( J \) . Thus our results will include the case where \( J \) is the conjugate transpose operation. We shall also show that there are linear spaces of real matrices closed under row by row (or column by column) multiplication and not under row by column multiplication, but that these row by row algebras cannot be semi-simple.
@article {key0009949m,
AUTHOR = {Albert, A. A.},
TITLE = {Algebras derived by non-associative
matrix multiplication},
JOURNAL = {Am. J. Math.},
FJOURNAL = {American Journal of Mathematics},
VOLUME = {66},
NUMBER = {1},
MONTH = {January},
YEAR = {1944},
PAGES = {30--40},
DOI = {10.2307/2371893},
NOTE = {MR:5,227b. Zbl:0061.05003.},
ISSN = {0002-9327},
}
A. A. Albert :
“Book review: Galois theory ,”
Bull. Am. Math. Soc.
51 : 5
(1945 ),
pp. 359 .
Book by Emil Artin (University of Notre Dame Press, 1942).
MR
1564714
article
People
BibTeX
@article {key1564714m,
AUTHOR = {Albert, A. A.},
TITLE = {Book review: {G}alois theory},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {51},
NUMBER = {5},
YEAR = {1945},
PAGES = {359},
DOI = {10.1090/S0002-9904-1945-08345-1},
NOTE = {Book by Emil Artin (University of Notre
Dame Press, 1942). MR:1564714.},
ISSN = {0002-9904},
}
A. A. Albert :
“On Jordan algebras of linear transformations ,”
Trans. Am. Math. Soc.
59
(1946 ),
pp. 524–555 .
MR
0016759
Zbl
0061.05101
article
Abstract
BibTeX
In the present paper we shall obtain the fundamental structure theorems for Jordan algebras over a nonmodular field. We shall derive analogues for Jordan algebras of the Lie and Engel theorems on solvable Lie algebras and shall obtain a trace criterion for the existence of a nonzero radical. The results imply a Pierce decomposition for a Jordan algebra relative to an idempotent which is almost precisely that known for any associative algebra. Then semisimple Jordan algebras have unity elements and are direct sums of simple algebras. The center of a simple Jordan algebra is a field and every simple Jordan algebra may be expressed as a central simple algebra over its center. If \( \mathfrak{A} \) is central simple every scalar extension \( \mathfrak{A}_{\mathfrak{K}} \) of \( \mathfrak{A} \) is simple.
We shall also show that if \( u \) is any primitive idempotent of a simple algebra \( \mathfrak{A} \) the associative product \( u\mathfrak{A} u \) is a simple subalgebra of \( \mathfrak{A} \) and has \( u \) as unity quantity. We shall call \( \mathfrak{A} \) a reduced algebra if \( \mathfrak{A} \) is simple and \( u\mathfrak{A}u \) has order one for every primitive idempotent \( u \) of \( \mathfrak{A} \) . Every central simple algebra has a scalar extension field \( \mathfrak{K} \) such that \( \mathfrak{A}_{\mathfrak{K}} \) is a reduced algebra, and we shall determine all reduced Jordan algebras.
@article {key0016759m,
AUTHOR = {Albert, A. A.},
TITLE = {On {J}ordan algebras of linear transformations},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {59},
YEAR = {1946},
PAGES = {524--555},
DOI = {10.2307/1990270},
NOTE = {MR:8,63c. Zbl:0061.05101.},
ISSN = {0002-9947},
}
A. A. Albert :
College algebra .
McGraw-Hill (New York ),
1946 .
Reprinted by Univ. Chicago press in 1963.
book
BibTeX
@book {key65057155,
AUTHOR = {Albert, A. A.},
TITLE = {College algebra},
PUBLISHER = {McGraw-Hill},
ADDRESS = {New York},
YEAR = {1946},
PAGES = {278},
NOTE = {Reprinted by Univ. Chicago press in
1963.},
}
A. A. Albert :
“A structure theory for Jordan algebras ,”
Ann. Math. (2)
48 : 3
(July 1947 ),
pp. 546–567 .
MR
0021546
Zbl
0029.01003
article
Abstract
BibTeX
@article {key0021546m,
AUTHOR = {Albert, A. A.},
TITLE = {A structure theory for {J}ordan algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {48},
NUMBER = {3},
MONTH = {July},
YEAR = {1947},
PAGES = {546--567},
DOI = {10.2307/1969128},
NOTE = {MR:9,77f. Zbl:0029.01003.},
ISSN = {0003-486X},
}
A. A. Albert :
“The Wedderburn principal theorem for Jordan algebras ,”
Ann. Math. (2)
48 : 1
(January 1947 ),
pp. 1–7 .
MR
0019601
Zbl
0029.01002
article
Abstract
BibTeX
@article {key0019601m,
AUTHOR = {Albert, A. A.},
TITLE = {The {W}edderburn principal theorem for
{J}ordan algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {48},
NUMBER = {1},
MONTH = {January},
YEAR = {1947},
PAGES = {1--7},
DOI = {10.2307/1969210},
NOTE = {MR:8,435b. Zbl:0029.01002.},
ISSN = {0003-486X},
}
A. A. Albert :
“Absolute valued real algebras ,”
Ann. Math. (2)
48 : 2
(April 1947 ),
pp. 495–501 .
MR
0020550
Zbl
0029.01001
article
Abstract
BibTeX
Let \( \mathfrak{D} \) be an algebra over the field \( \mathfrak{R} \) of all real numbers. Then we call \( \mathfrak{D} \) an absolute valued algebra if there is a function \( \phi(a) \) on \( \mathfrak{D} \) to \( \mathfrak{R} \) such that
\( \phi(0) = 0 \) ,
\( \phi(a) > 0 \) if \( a \neq 0 \) ,
\( \phi(ab) = \phi(a)\phi(b) \) ,
\( \phi(a+b) \leq \phi(a) + \phi(b) \) ,
\( \phi(\alpha a) = |\alpha|\phi(a) \) for every \( a \) and \( b \) of \( \mathfrak{D} \) and real \( \alpha \) where \( |\alpha| \) is the ordinary absolute value.
Then \( \phi(a\pm b) \geq |\phi(a) - \phi(b)| \) . Also \( \mathfrak{D} \) must be a division algebra. For if \( a\neq 0 \) , \( b\neq 0 \) , then
It is well known that the only alternative division algebras over \( \mathfrak{R} \) are the field \( \mathfrak{R} \) , the field \( \mathfrak{C} \) of all complex numbers, the algebra \( \mathfrak{Q} \) of all real quaternions, and the eight dimensional algebra \( \mathfrak{B} \) of all real Cayley numbers. Each of these algebras has a conjugate operation \( x\to \bar{x} \) such that \( x\bar{x} \) is a positive real number, and it is easy to see that \( \phi(x) = \sqrt{x\bar{x}} \) defines an absolute value for each algebra. A known result then implies that \( \phi(a) \) is unique. We shall prove here that the alternative division algebras are the only absolute valued real algebras with a unity quantity. This characterizes the Cayley algebra as the only absolute valued real algebra with a unity quantity which is not associative. We shall also show that all absolute valued real algebras without a unity quantity are certain isotopes of \( \mathfrak{Q} \) and \( \mathfrak{B} \) .
A real algebra \( \mathfrak{A} \) is called a normed algebra if the function \( \phi(a) \) is assumed to satisfy
\[ \phi(ab) \leq \phi(a)\phi(b) \]
rather than the equality. We shall show here that every real algebra is a normed algebra. Then there exist normed algebras which are not absolute valued.
@article {key0020550m,
AUTHOR = {Albert, A. A.},
TITLE = {Absolute valued real algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {48},
NUMBER = {2},
MONTH = {April},
YEAR = {1947},
PAGES = {495--501},
DOI = {10.2307/1969182},
NOTE = {MR:8,561d. Zbl:0029.01001.},
ISSN = {0003-486X},
}
A. A. Albert :
“Power-associative rings ,”
Trans. Am. Math. Soc.
64
(1948 ),
pp. 552–593 .
MR
0027750
Zbl
0033.15402
article
BibTeX
@article {key0027750m,
AUTHOR = {Albert, A. A.},
TITLE = {Power-associative rings},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {64},
YEAR = {1948},
PAGES = {552--593},
DOI = {10.2307/1990399},
NOTE = {MR:10,349g. Zbl:0033.15402.},
ISSN = {0002-9947},
}
A. A. Albert :
“On the power-associativity of rings ,”
Summa Brasil. Math.
2 : 2
(1948 ),
pp. 21–32 .
MR
0026044
Zbl
0039.26403
article
BibTeX
@article {key0026044m,
AUTHOR = {Albert, A. A.},
TITLE = {On the power-associativity of rings},
JOURNAL = {Summa Brasil. Math.},
FJOURNAL = {Summa Brasiliensis Mathematicae},
VOLUME = {2},
NUMBER = {2},
YEAR = {1948},
PAGES = {21--32},
NOTE = {MR:10,97d. Zbl:0039.26403.},
ISSN = {0039-498X},
}
A. A. Albert :
“On right alternative algebras ,”
Ann. Math. (2)
50 : 2
(April 1949 ),
pp. 318–328 .
MR
0028828
Zbl
0033.15501
article
Abstract
BibTeX
@article {key0028828m,
AUTHOR = {Albert, A. A.},
TITLE = {On right alternative algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {50},
NUMBER = {2},
MONTH = {April},
YEAR = {1949},
PAGES = {318--328},
DOI = {10.2307/1969457},
NOTE = {MR:10,503g. Zbl:0033.15501.},
ISSN = {0003-486X},
}
A. A. Albert :
“A theory of trace-admissible algebras ,”
Proc. Nat. Acad. Sci. U. S. A.
35
(1949 ),
pp. 317–322 .
MR
0030511
Zbl
0033.15403
article
Abstract
BibTeX
There have been a number of studies of non-associative algebras in which the lack of the associative law has been compensated for by the assumption of one or more other identities. The principal tool in most of these studies has been a trace argument, and the simple algebras, which are the end results, have invariably been of relatively special types.
In the present note we shall make a major advance in the theory of nonassociative algebras by obtaining a general theory which includes all previous theories in which the radical was defined to be the maximal nilideal.
@article {key0030511m,
AUTHOR = {Albert, A. A.},
TITLE = {A theory of trace-admissible algebras},
JOURNAL = {Proc. Nat. Acad. Sci. U. S. A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {35},
YEAR = {1949},
PAGES = {317--322},
DOI = {10.1073/pnas.35.6.317},
NOTE = {MR:11,6b. Zbl:0033.15403.},
ISSN = {0027-8424},
}
A. A. Albert :
“Absolute-valued algebraic algebras ,”
Bull. Am. Math. Soc.
55 : 8
(1949 ),
pp. 763–768 .
MR
0030941
Zbl
0033.34901
article
Abstract
BibTeX
An algebra \( \mathfrak{A} \) over a field \( \mathfrak{F} \) is a vector space over \( \mathfrak{F} \) which is closed with respect to a product \( xy \) which is linear in both \( x \) and \( y \) . The product is not necessarily associative. Every element \( x \) of \( \mathfrak{A} \) generates a subalgebra \( \mathfrak{F}[x] \) of \( \mathfrak{A} \) and we call \( \mathfrak{A} \) an algebraic algebra if every \( \mathfrak{F}[x] \) is a finite-dimensional vector space over \( \mathfrak{F} \) .
We have shown elsewhere [1947] that every absolute-valued real finite-dimensional algebra has dimension 1, 2, 4, or 8 and is either the field \( \mathfrak{R} \) of all real numbers, the complex field \( \mathfrak{C} \) , the real quaternion algebra \( \mathfrak{Q} \) , the real Cayley algebra \( \mathfrak{D} \) , or certain isotopes without unity quantities of \( \mathfrak{Q} \) and \( \mathfrak{D} \) . In the present paper we shall extend these results to algebraic algebras over \( \mathfrak{R} \) showing that every algebraic algebra over \( \mathfrak{R} \) with a unity quantity is finite-dimensional and so is one of the algebras listed above. The results are extended immediately to absolute-valued algebraic division algebras, that is, to algebras without unity quantities whose nonzero quantities form a quasigroup.
@article {key0030941m,
AUTHOR = {Albert, A. A.},
TITLE = {Absolute-valued algebraic algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {55},
NUMBER = {8},
YEAR = {1949},
PAGES = {763--768},
DOI = {10.1090/S0002-9904-1949-09278-9},
NOTE = {MR:11,76h. Zbl:0033.34901.},
ISSN = {0002-9904},
}
A. A. Albert :
“A note of correction ,”
Bull. Am. Math. Soc.
55
(1949 ),
pp. 1191 .
Correction to paper in Bull. Am. Math. Soc. 55 :8 (1949) .
MR
0030942
article
BibTeX
@article {key0030942m,
AUTHOR = {Albert, A. A.},
TITLE = {A note of correction},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {55},
YEAR = {1949},
PAGES = {1191},
DOI = {10.1090/S0002-9904-1949-09358-8},
NOTE = {Correction to paper in \textit{Bull.
Am. Math. Soc.} \textbf{55}:8 (1949).
MR:11,76i.},
ISSN = {0002-9904},
}
A. A. Albert :
“Almost alternative algebras ,”
Port. Math.
8
(1949 ),
pp. 23–36 .
MR
0032609
Zbl
0033.15401
article
BibTeX
@article {key0032609m,
AUTHOR = {Albert, A. A.},
TITLE = {Almost alternative algebras},
JOURNAL = {Port. Math.},
FJOURNAL = {Portugaliae Mathematica},
VOLUME = {8},
YEAR = {1949},
PAGES = {23--36},
NOTE = {MR:11,316f. Zbl:0033.15401.},
ISSN = {0032-5155},
}
A. A. Albert :
Solid analytic geometry .
McGraw-Hill (New York ),
1949 .
Reprinted by Univ. Chicago press in 1966.
book
BibTeX
@book {key70395593,
AUTHOR = {Albert, A. A.},
TITLE = {Solid analytic geometry},
PUBLISHER = {McGraw-Hill},
ADDRESS = {New York},
YEAR = {1949},
PAGES = {158},
NOTE = {Reprinted by Univ. Chicago press in
1966.},
}
A. A. Albert :
“A theory of power-associative commutative algebras ,”
Trans. Am. Math. Soc.
69 : 3
(November 1950 ),
pp. 503–527 .
MR
0038959
Zbl
0039.26501
article
Abstract
BibTeX
In any study of a class of linear algebras the main goal is usually that of determining the simple algebras. The author has recently made a number of such studies for classes of power-associative algebras defined by identities [1948] or by the existence of a trace function [1949], and the results have been somewhat surprising in that the commutative simple algebras have all been Jordan algebras.
In the present paper we shall derive the reason for this fact. Moreover we shall derive a structure theory which includes the structure theory for Jordan algebras of characteristic \( p \) .
@article {key0038959m,
AUTHOR = {Albert, A. A.},
TITLE = {A theory of power-associative commutative
algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {69},
NUMBER = {3},
MONTH = {November},
YEAR = {1950},
PAGES = {503--527},
DOI = {10.2307/1990496},
NOTE = {MR:12,475d. Zbl:0039.26501.},
ISSN = {0002-9947},
}
A. A. Albert :
“A note on the exceptional Jordan algebra ,”
Proc. Nat. Acad. Sci. U. S. A.
36 : 7
(July 1950 ),
pp. 372–374 .
MR
0035753
Zbl
0037.15904
article
Abstract
BibTeX
An associative algebra \( \mathfrak{A} \) over a field \( \mathfrak{F} \) is a vector space over \( \mathfrak{F} \) together with an associative bilinear operation \( xy \) . When the characteristic of \( \mathfrak{F} \) is not two we can use the same vector space and define a new algebra \( \mathfrak{A}^{(+)} \) relative to the operation \( \frac{1}{2}(xy + yx) \) . This algebra is a Jordan algebra. Any Jordan algebra \( \mathfrak{J} \) is called a special Jordan algebra if \( \mathfrak{J} \) is isomorphic to a Jordan subalgebra of some \( \mathfrak{A}^{(+)} \) .
In 1934 it was shown that the Jordan algebra \( \mathfrak{G} \) of all three-rowed Hermitian matrices with elements in the simple eight-dimensional Cayley algebra \( \mathfrak{C} \) is exceptional in the limited sense that \( \mathfrak{G} \) is not isomorphic to a subalgebra of a finite-dimensional \( \mathfrak{A}^{(+)} \) . In the present note we shall give a simpler proof of the fact that \( \mathfrak{G} \) is not a special Jordan algebra and shall delete the restriction that \( \mathfrak{A} \) be finite dimensional . We shall assume that \( \mathfrak{G} \) is imbedded in an associative algebra \( \mathfrak{A} \) and shall then obtain a contradiction by showing that the enveloping associative algebra of \( \mathfrak{G} \) contains a subalgebra isomorphic to the non-associative algebra \( \mathfrak{T} \) .
@article {key0035753m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on the exceptional {J}ordan algebra},
JOURNAL = {Proc. Nat. Acad. Sci. U. S. A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {36},
NUMBER = {7},
MONTH = {July},
YEAR = {1950},
PAGES = {372--374},
DOI = {10.1073/pnas.36.7.372},
NOTE = {MR:12,5h. Zbl:0037.15904.},
ISSN = {0027-8424},
}
A. A. Albert :
“New simple power-associative algebras ,”
Summa Brasil. Math.
2
(1951 ),
pp. 183–194 .
MR
0048421
Zbl
0045.32101
article
BibTeX
@article {key0048421m,
AUTHOR = {Albert, A. A.},
TITLE = {New simple power-associative algebras},
JOURNAL = {Summa Brasil. Math.},
FJOURNAL = {Summa Brasiliensis Mathematicae},
VOLUME = {2},
YEAR = {1951},
PAGES = {183--194},
NOTE = {MR:14,11e. Zbl:0045.32101.},
ISSN = {0039-498X},
}
A. A. Albert :
“On simple alternative rings ,”
Can. J. Math.
4 : 2
(1952 ),
pp. 129–135 .
MR
0048420
Zbl
0046.25403
article
Abstract
BibTeX
The only known simple alternative rings which are not associative are the Cayley algebras . Every such algebra has a scalar extension which is isomorphic over its center \( \mathsf{F} \) to the algebra
\[ \mathsf{C} = e_{11}\mathsf{F} + e_{00}\mathsf{F} + \mathsf{C}_{10} + \mathsf{C}_{01} ,\]
where
\[ \mathsf{C}_{ij} = e_{ij}\mathsf{F} + f_{ij}\mathsf{F} + g_{ij}\mathsf{F} \qquad (i,j = 0,1;\ i \neq j) .\]
The elements \( e_{11} \) and \( e_{00} \) are orthogonal idempotents and
\[ e_{ii}x_{ij} = x_{ij}e_{jj} = x_{ij},\quad e_{jj}x_{ij} = x_{ij}e_{ii} = 0,\quad x_{ij}^2 = 0 \]
for every \( x_{ij} \) of \( \mathsf{C}_{ij} \) . The multiplication table of \( \mathsf{C} \) is then completed by the relations
\begin{gather*} f_{10}g_{10} = e_{01},\quad g_{10}e_{10} = f_{01},\quad e_{10}f_{10} = g_{01},\\ g_{01}f_{01} = e_{10},\quad e_{01}g_{01} = f_{10},\quad f_{01}e_{01} = g_{10},\\ e_{ij}e_{ji} = f_{ij}f_{ji} = g_{ij}e_{ji} = e_{ii},\\ e_{ij}f_{ji} = e_{ij}g_{ji} = f_{ij}e_{ji} = f_{ij}g_{ji} = g_{ij}e_{ij} = g_{ij}f_{ij} = 0. \end{gather*}
Every simple alternative ring which contains an idempotent not its unity quantity is either associative or is the Cayley algebra \( \mathsf{C} \) .
@article {key0048420m,
AUTHOR = {Albert, A. A.},
TITLE = {On simple alternative rings},
JOURNAL = {Can. J. Math.},
FJOURNAL = {Canadian Journal of Mathematics},
VOLUME = {4},
NUMBER = {2},
YEAR = {1952},
PAGES = {129--135},
DOI = {10.4153/CJM-1952-013-x},
NOTE = {MR:14,11d. Zbl:0046.25403.},
ISSN = {0008-414X},
}
A. A. Albert :
“Power-associative algebras ,”
pp. 25–32
in
Proceedings of the International Congress of Mathematicians
(Cambridge, MA, 30 August–6 September, 1950 ),
vol. 2 .
American Mathematical Society (Providence, RI ),
1952 .
MR
0045103
Zbl
0049.02401
incollection
BibTeX
@incollection {key0045103m,
AUTHOR = {Albert, A. A.},
TITLE = {Power-associative algebras},
BOOKTITLE = {Proceedings of the {I}nternational {C}ongress
of {M}athematicians},
VOLUME = {2},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1952},
PAGES = {25--32},
URL = {http://ada00.math.uni-bielefeld.de/ICM/ICM1950.2/Main/icm1950.2.0025.0032.ocr.pdf},
NOTE = {(Cambridge, MA, 30 August--6 September,
1950). MR:13,527d. Zbl:0049.02401.},
}
A. A. Albert :
“On nonassociative division algebras ,”
Trans. Am. Math. Soc.
72
(1952 ),
pp. 296–309 .
MR
0047027
Zbl
0046.03601
article
Abstract
BibTeX
One of our main results is a generalization of the Wedderburn–Artin Theorem on finite division algebras. We shall show that every finite power-associative division algebra of characteristic \( p > 5 \) is a finite field .
The remainder of the paper is devoted to showing that the Wedderburn Theorem for finite division algebras depends upon some assumption such as power-associativity.
@article {key0047027m,
AUTHOR = {Albert, A. A.},
TITLE = {On nonassociative division algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {72},
YEAR = {1952},
PAGES = {296--309},
DOI = {10.2307/1990756},
NOTE = {MR:13,816d. Zbl:0046.03601.},
ISSN = {0002-9947},
}
A. A. Albert :
“On commutative power-associative algebras of degree two ,”
Trans. Am. Math. Soc.
74
(1953 ),
pp. 323–343 .
MR
0052409
Zbl
0051.02302
article
Abstract
BibTeX
The study of the structure of any simple commutative power-associative algebra \( \mathfrak{A} \) over a field \( \mathfrak{F} \) begins with the case where \( \mathfrak{F} \) is algebraically closed. We shall also assume that the characteristic of \( \mathfrak{F} \) is prime to 30. Then \( \mathfrak{A} \) has a unity quantity 1 which is expressible as the sum
\[ 1=u_1+\cdots+u_t \]
of pairwise orthogonal (absolutely) primitive idempotents \( u_i \) . The integer \( t \) is unique and is called the degree of \( \mathfrak{A} \) . It is known that if \( t > 2 \) , the algebra \( \mathfrak{A} \) is a classical Jordan algebra. The structure of algebras of degree two is not known and will be considered here.
@article {key0052409m,
AUTHOR = {Albert, A. A.},
TITLE = {On commutative power-associative algebras
of degree two},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {74},
YEAR = {1953},
PAGES = {323--343},
DOI = {10.2307/1990885},
NOTE = {MR:14,614h. Zbl:0051.02302.},
ISSN = {0002-9947},
}
A. A. Albert :
“Rational normal matrices satisfying the incidence equation ,”
Proc. Am. Math. Soc.
4
(1953 ),
pp. 554–559 .
MR
0056570
Zbl
0050.01004
article
Abstract
BibTeX
@article {key0056570m,
AUTHOR = {Albert, A. A.},
TITLE = {Rational normal matrices satisfying
the incidence equation},
JOURNAL = {Proc. Am. Math. Soc.},
FJOURNAL = {Proceedings of the American Mathematical
Society},
VOLUME = {4},
YEAR = {1953},
PAGES = {554--559},
DOI = {10.2307/2032523},
NOTE = {MR:15,94e. Zbl:0050.01004.},
ISSN = {0002-9939},
}
A. A. Albert :
“The structure of right alternative algebras ,”
Ann. Math. (2)
59 : 3
(May 1954 ),
pp. 408–417 .
MR
0061096
Zbl
0055.26501
article
Abstract
BibTeX
An algebra \( \mathfrak{A} \) over a field \( \mathfrak{F} \) is said to be right alternative if \( (yx)x = y(xx) \) for every \( x \) and \( y \) of \( \mathfrak{A} \) . Some properties of right alternative agebras have been obtained, and it is known that every simple right alternative algebra of characteristic zero is alternative .
In the present paper we shall derive a structure theory for right alternative algebras over any field \( \mathfrak{F} \) of characteristic not two . We shall define a trace function for such algebras and shall show that this trace function has the properties which imply that the ordinary trace criterion for the radical is valid. Our results will then lead to the theorem which states that every semisimple right alternative algebra of characteristic not two is alternative .
@article {key0061096m,
AUTHOR = {Albert, A. A.},
TITLE = {The structure of right alternative algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {59},
NUMBER = {3},
MONTH = {May},
YEAR = {1954},
PAGES = {408--417},
DOI = {10.2307/1969709},
NOTE = {MR:15,774b. Zbl:0055.26501.},
ISSN = {0003-486X},
}
A. A. Albert and M. S. Frank :
“Simple Lie algebras of characteristic \( p \) ,”
Rend. Sem. Mat. Univ. Politec. Torino
14
(1954/1955 ),
pp. 117–139 .
MR
0079222
Zbl
0065.26801
article
People
BibTeX
@article {key0079222m,
AUTHOR = {Albert, A. A. and Frank, M. S.},
TITLE = {Simple {L}ie algebras of characteristic
\$p\$},
JOURNAL = {Rend. Sem. Mat. Univ. Politec. Torino},
FJOURNAL = {Rendiconti del Seminario Matematico.
Universit\`a e Politecnico, Torino},
VOLUME = {14},
YEAR = {1954/1955},
PAGES = {117--139},
NOTE = {MR:18,52a. Zbl:0065.26801.},
ISSN = {0373-1243},
}
A. A. Albert :
“Leonard Eugene Dickson, 1874–1954 ,”
Bull. Am. Math. Soc.
61
(1955 ),
pp. 331–345 .
MR
0070564
Zbl
0065.24408
article
People
BibTeX
@article {key0070564m,
AUTHOR = {Albert, A. A.},
TITLE = {Leonard {E}ugene {D}ickson, 1874--1954},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {61},
YEAR = {1955},
PAGES = {331--345},
DOI = {10.1090/S0002-9904-1955-09937-3},
NOTE = {MR:17,2p. Zbl:0065.24408.},
ISSN = {0002-9904},
}
A. A. Albert :
“On Hermitian operators over the Cayley algebra ,”
Proc. Nat. Acad. Sci. U. S. A.
41 : 9
(September 1955 ),
pp. 639–640 .
MR
0071416
Zbl
0065.02002
article
Abstract
BibTeX
@article {key0071416m,
AUTHOR = {Albert, A. A.},
TITLE = {On {H}ermitian operators over the {C}ayley
algebra},
JOURNAL = {Proc. Nat. Acad. Sci. U. S. A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {41},
NUMBER = {9},
MONTH = {September},
YEAR = {1955},
PAGES = {639--640},
DOI = {10.1073/pnas.41.9.639},
NOTE = {MR:17,123c. Zbl:0065.02002.},
ISSN = {0027-8424},
}
A. A. Albert :
“On involutorial algebras ,”
Proc. Nat. Acad. Sci. U.S.A.
41 : 7
(July 1955 ),
pp. 480–482 .
MR
0070623
Zbl
0064.27201
article
Abstract
BibTeX
@article {key0070623m,
AUTHOR = {Albert, A. A.},
TITLE = {On involutorial algebras},
JOURNAL = {Proc. Nat. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {41},
NUMBER = {7},
MONTH = {July},
YEAR = {1955},
PAGES = {480--482},
DOI = {10.1073/pnas.41.7.480},
NOTE = {MR:17,9c. Zbl:0064.27201.},
ISSN = {0027-8424},
}
A. A. Albert :
“A property of special Jordan algebras ,”
Proc. Nat. Acad. Sci. U.S.A.
42 : 9
(September 1956 ),
pp. 624–625 .
MR
0081271
Zbl
0071.25803
article
Abstract
BibTeX
Let \( \mathfrak{B} \) be a Jordan algebra with radical \( \mathfrak{H} \) such that \( \mathfrak{B} \) is the homomorphic image of a special Jordan algebra \( \mathfrak{A} \) . Then \( \mathfrak{B} - \mathfrak{H} \) is a special Jordan algebra.
@article {key0081271m,
AUTHOR = {Albert, A. A.},
TITLE = {A property of special {J}ordan algebras},
JOURNAL = {Proc. Nat. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {42},
NUMBER = {9},
MONTH = {September},
YEAR = {1956},
PAGES = {624--625},
DOI = {10.1073/pnas.42.9.624},
NOTE = {MR:18,375f. Zbl:0071.25803.},
ISSN = {0027-8424},
}
A. A. Albert :
“A property of ordered rings ,”
Proc. Am. Math. Soc.
8
(1957 ),
pp. 128–129 .
MR
0082480
Zbl
0081.26401
article
Abstract
BibTeX
@article {key0082480m,
AUTHOR = {Albert, A. A.},
TITLE = {A property of ordered rings},
JOURNAL = {Proc. Am. Math. Soc.},
FJOURNAL = {Proceedings of the American Mathematical
Society},
VOLUME = {8},
YEAR = {1957},
PAGES = {128--129},
DOI = {10.2307/2032825},
NOTE = {MR:18,557a. Zbl:0081.26401.},
ISSN = {0002-9939},
}
A. A. Albert :
“On certain trinomial equations in finite fields ,”
Ann. Math. (2)
66 : 1
(July 1957 ),
pp. 170–178 .
MR
0087691
Zbl
0082.03702
article
Abstract
BibTeX
Let \( \mathfrak{F} = \mathfrak{F}_q \) be a field of \( q = \pi^m \) elements where the prime \( \pi \) is the characteristic of \( \mathfrak{F} \) , and \( \mathfrak{K} \) be a field of degree \( n \) over \( \mathfrak{F} \) . If \( y \) is a primitive element of \( \mathfrak{K} \) its period (order as an element of the multiplicative group \( \mathfrak{K}^* \) of all non-zero elements of \( \mathfrak{K} \) ) is \( q^n - 1 \) , and every element of \( \mathfrak{K}^* \) is a power of \( y \) . It follows that if \( s \) is any integer not divisible by \( q^n - 1 \) there exists an integer \( t \) such that
\begin{equation*}\tag{1} x^s + y^t = 1. \end{equation*}
When \( y \) is not primitive there may be no solution pair \( (s,t) \) of equation (1). Indeed it is easy to show that no solution pair exists in the case where the period of \( y \) is a prime \( p > 3 \) such that \( q \) is primitive modulo \( p \) . It is then of some interest to study the question of the existence of solution pairs for some special values of the element \( y \) .
In this paper we shall consider the case where \( y = x - 1 \) for \( x \) an element of prime period \( p > 3 \) such that \( q \) is primitive modulo \( p \) . We shall restrict our attention to those solution pairs with \( s \) and \( t \) prime to \( p \) and shall determine all such solutions. We shall also separate the solutions into classes relative to conjugacy.
@article {key0087691m,
AUTHOR = {Albert, A. A.},
TITLE = {On certain trinomial equations in finite
fields},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {66},
NUMBER = {1},
MONTH = {July},
YEAR = {1957},
PAGES = {170--178},
DOI = {10.2307/1970123},
NOTE = {MR:19,394d. Zbl:0082.03702.},
ISSN = {0003-486X},
}
A. A. Albert and B. Muckenhoupt :
“On matrices of trace zero ,”
Michigan Math. J.
4 : 1
(1957 ),
pp. 1–3 .
MR
0083961
Zbl
0077.24304
article
Abstract
People
BibTeX
In [1937], K. Shoda showed that if \( M \) is any \( n \) -rowed square matrix with elements in a field \( \mathfrak{F} \) of characteristic zero, and \( M \) has trace \( \tau(M) = 0 \) , then there exist square matrices \( A \) and \( B \) with elements in \( \mathfrak{F} \) such that \( M = AB - BA \) . Shoda’s proof is not valid for a field \( \mathfrak{F} \) of characteristic \( p \) . The purpose of this note is to furnish a proof holding for any field \( \mathfrak{F} \) .
@article {key0083961m,
AUTHOR = {Albert, A. A. and Muckenhoupt, Benjamin},
TITLE = {On matrices of trace zero},
JOURNAL = {Michigan Math. J.},
FJOURNAL = {The Michigan Mathematical Journal},
VOLUME = {4},
NUMBER = {1},
YEAR = {1957},
PAGES = {1--3},
URL = {http://projecteuclid.org/euclid.mmj/1028990168},
NOTE = {MR:18,786b. Zbl:0077.24304.},
ISSN = {0026-2285},
}
A. A. Albert :
“On partially stable algebras ,”
Trans. Am. Math. Soc.
84 : 2
(1957 ),
pp. 430–443 .
MR
0092778
Zbl
0077.25603
article
Abstract
BibTeX
@article {key0092778m,
AUTHOR = {Albert, A. A.},
TITLE = {On partially stable algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {84},
NUMBER = {2},
YEAR = {1957},
PAGES = {430--443},
DOI = {10.2307/1992824},
NOTE = {MR:19,1156f. Zbl:0077.25603.},
ISSN = {0002-9947},
}
A. A. Albert :
“The norm form of a rational division algebra ,”
Proc. Nat. Acad. Sci. U.S.A.
43 : 6
(1957 ),
pp. 506–509 .
MR
0086807
Zbl
0078.02602
article
Abstract
BibTeX
@article {key0086807m,
AUTHOR = {Albert, A. A.},
TITLE = {The norm form of a rational division
algebra},
JOURNAL = {Proc. Nat. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {43},
NUMBER = {6},
YEAR = {1957},
PAGES = {506--509},
DOI = {10.1073/pnas.43.6.506},
NOTE = {MR:19,246f. Zbl:0078.02602.},
ISSN = {0027-8424},
}
A. A. Albert and N. Jacobson :
“On reduced exceptional simple Jordan algebras ,”
Ann. Math. (2)
66 : 3
(November 1957 ),
pp. 400–417 .
MR
0088487
Zbl
0079.04604
article
People
BibTeX
@article {key0088487m,
AUTHOR = {Albert, A. A. and Jacobson, N.},
TITLE = {On reduced exceptional simple {J}ordan
algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {66},
NUMBER = {3},
MONTH = {November},
YEAR = {1957},
PAGES = {400--417},
DOI = {10.2307/1969898},
NOTE = {MR:19,527b. Zbl:0079.04604.},
ISSN = {0003-486X},
}
A. A. Albert :
“On the orthogonal equivalence of sets of real symmetric matrices ,”
J. Math. Mech.
7
(1958 ),
pp. 219–235 .
MR
0092753
Zbl
0087.01203
article
BibTeX
@article {key0092753m,
AUTHOR = {Albert, A. A.},
TITLE = {On the orthogonal equivalence of sets
of real symmetric matrices},
JOURNAL = {J. Math. Mech.},
FJOURNAL = {Journal of Mathematics and Mechanics},
VOLUME = {7},
YEAR = {1958},
PAGES = {219--235},
NOTE = {MR:19,1153c. Zbl:0087.01203.},
ISSN = {0095-9057},
}
A. A. Albert :
“Finite noncommutative division algebras ,”
Proc. Am. Math. Soc.
9
(1958 ),
pp. 928–932 .
MR
0103212
Zbl
0092.03501
article
Abstract
BibTeX
@article {key0103212m,
AUTHOR = {Albert, A. A.},
TITLE = {Finite noncommutative division algebras},
JOURNAL = {Proc. Am. Math. Soc.},
FJOURNAL = {Proceedings of the American Mathematical
Society},
VOLUME = {9},
YEAR = {1958},
PAGES = {928--932},
DOI = {10.2307/2033331},
NOTE = {MR:21 \#1994. Zbl:0092.03501.},
ISSN = {0002-9939},
}
A. A. Albert and J. Thompson :
“Two element generation of the projective unimodular group ,”
Bull. Am. Math. Soc.
64
(1958 ),
pp. 92–93 .
MR
0096728
Zbl
0082.02605
article
Abstract
People
BibTeX
In [1930] H. R. Brahana gave pairs of generators of the known simple groups whose orders are less than one million, and showed that one of the generators can be taken to have period two. In this note we shall outline our proof of the corresponding result for the general case of the projective unimodular group.
@article {key0096728m,
AUTHOR = {Albert, A. A. and Thompson, John},
TITLE = {Two element generation of the projective
unimodular group},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {64},
YEAR = {1958},
PAGES = {92--93},
DOI = {10.1090/S0002-9904-1958-10169-X},
NOTE = {MR:20 \#3211. Zbl:0082.02605.},
ISSN = {0002-9904},
}
A. A. Albert :
“Addendum to the paper on partially stable algebras ,”
Trans. Am. Math. Soc.
87
(1958 ),
pp. 57–62 .
Addendum to paper in Trans. Am. Math. Soc. 84 :2 (1957) .
MR
0092779
Zbl
0083.02603
article
BibTeX
@article {key0092779m,
AUTHOR = {Albert, A. A.},
TITLE = {Addendum to the paper on partially stable
algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {87},
YEAR = {1958},
PAGES = {57--62},
DOI = {10.2307/1993086},
NOTE = {Addendum to paper in \textit{Trans.
Am. Math. Soc.} \textbf{84}:2 (1957).
MR:19,1157a. Zbl:0083.02603.},
ISSN = {0002-9947},
}
A. A. Albert :
Fundamental concepts of higher algebra .
University of Chicago Press ,
1958 .
Chapter 5 translated into Russian in Kibern. Sb. 3 (1966) .
MR
0098735
Zbl
0073.00802
book
BibTeX
@book {key0098735m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Fundamental concepts of higher algebra},
PUBLISHER = {University of Chicago Press},
YEAR = {1958},
PAGES = {ix+165},
NOTE = {Chapter 5 translated into Russian in
\textit{Kibern. Sb.} \textbf{3} (1966).
MR:20 \#5190. Zbl:0073.00802.},
}
A. A. Albert :
“A construction of exceptional Jordan division algebras ,”
Ann. Math. (2)
67 : 1
(January 1958 ),
pp. 1–28 .
MR
0091946
Zbl
0079.04701
article
Abstract
BibTeX
We shall construct a class of central simple exceptional Jordan algebras \( \mathfrak{H} \) over any field \( \mathfrak{F} \) of characteristic not two which we shall call cyclic Jordan algebras. Each such algebra \( \mathfrak{H} \) has an attached cyclic associative algebra \( \mathfrak{D} = (\mathfrak{K},S,\tau) \) of degree three over its center \( \mathfrak{F} \) , and an attached Cayley algebra \( \mathfrak{C} \) over \( \mathfrak{K} \) having a nonsingular linear transformation \( T \) over \( \mathfrak{F} \) inducing \( S \) in \( \mathfrak{K} \) and such that
\[ [(xy)T]\overline{g} = (xT)(yT\bar{g}), \qquad xT^3 = g^{-1}xg \]
for \( g = gT \) in \( \mathfrak{C} \) . We shall determine \( T \) completely in the case where \( \mathfrak{F}[g] \) is the direct sum of two copies of \( \mathfrak{F} \) , and shall show that \( T \) is uniquely determined by a parameter \( \sigma \) in \( \mathfrak{F} \) . When \( \mathfrak{D} \) is not a division algebra the cyclic algebra \( \mathfrak{H} \) is reduced. When \( \mathfrak{D} \) is a division algebra we can write \( \mathfrak{H} = \mathfrak{F}(\mathfrak{K},\tau,\sigma) \) and can show that every such \( \mathfrak{H} \) contains a subalgebra of dimension nine over \( \mathfrak{F} \) containing no singular elements. The norm form of \( \mathfrak{D} \) is a cubic form \( \Delta(x) \) in the nine coordinates of the general element \( x \) of \( \mathfrak{D} \) , and we shall show that \( \mathfrak{H} \) contains a singular element if and only if \( \sigma = \Delta(x) \) for some \( x \) of \( \mathfrak{D} \) . Also \( \mathfrak{H} \) is reduced if and only if \( \sigma = \Delta(x) \) . It follows that every simple exceptional Jordan algebra over an algebraic number field is reduced. However, if \( \mathfrak{F}_0 \) is any field of characteristic not two such that there exists a cyclic associative division algebra \( \mathfrak{D}_0 = (\mathfrak{K}_0, S, \tau) \) over \( \mathfrak{F}_0 \) , and \( \sigma \) is an indeterminate over \( \mathfrak{F}_0 \) , the cyclic Jordan algebra \( \mathfrak{H} = \mathfrak{H}(\mathfrak{K}_{0\mathfrak{F}}, \tau, \sigma) \) over \( \mathfrak{F} = \mathfrak{F}_0(\sigma) \) is not reduced and contains no divisors of zero.
@article {key0091946m,
AUTHOR = {Albert, A. A.},
TITLE = {A construction of exceptional {J}ordan
division algebras},
JOURNAL = {Ann. Math. (2)},
FJOURNAL = {Annals of Mathematics. Second Series},
VOLUME = {67},
NUMBER = {1},
MONTH = {January},
YEAR = {1958},
PAGES = {1--28},
DOI = {10.2307/1969922},
NOTE = {MR:19,1036b. Zbl:0079.04701.},
ISSN = {0003-486X},
}
A. A. Albert :
“On the collineation groups associated with twisted fields ,”
pp. 485–497
in
Calcutta Mathematical Society Golden Jubilee Commemoration (1958/59) ,
part II .
Calcutta Mathematical Society ,
1958/1959 .
MR
0159854
Zbl
0163.28003
incollection
BibTeX
@incollection {key0159854m,
AUTHOR = {Albert, A. A.},
TITLE = {On the collineation groups associated
with twisted fields},
BOOKTITLE = {Calcutta {M}athematical {S}ociety {G}olden
{J}ubilee {C}ommemoration (1958/59)},
VOLUME = {II},
PUBLISHER = {Calcutta Mathematical Society},
YEAR = {1958/1959},
PAGES = {485--497},
NOTE = {MR:28 \#3070. Zbl:0163.28003.},
}
A. A. Albert and L. J. Paige :
“On a homomorphism property of certain Jordan algebras ,”
Trans. Am. Math. Soc.
93
(1959 ),
pp. 20–29 .
MR
0108524
Zbl
0089.02001
article
Abstract
People
BibTeX
@article {key0108524m,
AUTHOR = {Albert, A. A. and Paige, L. J.},
TITLE = {On a homomorphism property of certain
{J}ordan algebras},
JOURNAL = {Trans. Am. Math. Soc.},
FJOURNAL = {Transactions of the American Mathematical
Society},
VOLUME = {93},
YEAR = {1959},
PAGES = {20--29},
DOI = {10.2307/1993420},
NOTE = {MR:21 \#7240. Zbl:0089.02001.},
ISSN = {0002-9947},
}
A. A. Albert and J. Thompson :
“Two-element generation of the projective unimodular group ,”
Ill. J. Math.
3 : 3
(1959 ),
pp. 421–439 .
MR
0106951
Zbl
0098.02302
article
Abstract
People
BibTeX
Let \( \mathfrak{F} = \mathfrak{F}_q \) be the field of \( q = p^m \) elements, \( \mathfrak{M} = \mathfrak{M}(n,q) \) the multiplicative group of all \( n \) -rowed square matrices with elements in and determinant 1, and \( \mathfrak{N} = \mathfrak{N}(n,q) \) the subgroup of \( \mathfrak{M} \) consisting of its scalar matrices \( \rho I \) with \( \rho^n = 1 \) . We assume, of course, that \( n > 1 \) . Then \( \mathfrak{N} \) is a normal subgroup of \( \mathfrak{N} \) , and the quotient group
\[ \mathfrak{G}=\mathfrak{G}(n,q)=\mathfrak{M}/\mathfrak{N} \]
is a well-known simple group called the projective unimodular group .
In [1930] H. R. Brahana gave a list of simple groups of orders less than 1,000,000. An examination of his list reveals the fact that every group there is generated by two elements, one of which has period (group order) two. The purpose of this paper is to prove the corresponding result for a general class of simple groups. We shall derive the following property.
The projective unimodular group is generated by two elements \( A\mathfrak{N} \) and \( B\mathfrak{N} \) , where the coset \( A\mathfrak{N} \) has period two.
@article {key0106951m,
AUTHOR = {Albert, A. A. and Thompson, John},
TITLE = {Two-element generation of the projective
unimodular group},
JOURNAL = {Ill. J. Math.},
FJOURNAL = {Illinois Journal of Mathematics},
VOLUME = {3},
NUMBER = {3},
YEAR = {1959},
PAGES = {421--439},
URL = {http://projecteuclid.org/euclid.ijm/1255455263},
NOTE = {MR:21 \#5681. Zbl:0098.02302.},
ISSN = {0019-2082},
}
A. A. Albert :
“A solvable exceptional Jordan algebra ,”
J. Math. Mech.
8
(1959 ),
pp. 331–337 .
MR
0101875
Zbl
0204.04101
article
BibTeX
@article {key0101875m,
AUTHOR = {Albert, A. A.},
TITLE = {A solvable exceptional {J}ordan algebra},
JOURNAL = {J. Math. Mech.},
FJOURNAL = {Journal of Mathematics and Mechanics},
VOLUME = {8},
YEAR = {1959},
PAGES = {331--337},
NOTE = {MR:21 \#681. Zbl:0204.04101.},
ISSN = {0095-9057},
}
A. A. Albert :
“On the collineation groups of certain non-desarguesian planes ,”
Port. Math.
18
(1959 ),
pp. 207–224 .
MR
0130613
Zbl
0099.15203
article
BibTeX
@article {key0130613m,
AUTHOR = {Albert, A. A.},
TITLE = {On the collineation groups of certain
non-desarguesian planes},
JOURNAL = {Port. Math.},
FJOURNAL = {Portugaliae Mathematica},
VOLUME = {18},
YEAR = {1959},
PAGES = {207--224},
NOTE = {MR:24 \#A473. Zbl:0099.15203.},
ISSN = {0032-5155},
}
Finite groups
(New York, 23–24 April, 1959 ).
Edited by A. A. Albert and I. Kaplansky .
Proceedings of Symposia in Pure Mathematics 1 .
American Mathematical Society (Providence, RI ),
1959 .
Zbl
0097.25602
book
People
BibTeX
@book {key0097.25602z,
TITLE = {Finite groups},
EDITOR = {Albert, A. A. and Kaplansky, Irving},
SERIES = {Proceedings of Symposia in Pure Mathematics},
NUMBER = {1},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1959},
PAGES = {vii+110},
NOTE = {(New York, 23--24 April, 1959). Zbl:0097.25602.},
ISBN = {9780821814017},
}
A. A. Albert :
“Finite division algebras and finite planes ,”
pp. 53–70
in
Combinatorial analysis
(Columbia University, New York, April 24–26, 1958 ).
Edited by R. E. Bellman and M. Hall, Jr.
Proceedings of Symposia in Applied Mathematics 10 .
American Mathematical Society (Providence, RI ),
1960 .
MR
0116036
Zbl
0096.15003
incollection
People
BibTeX
@incollection {key0116036m,
AUTHOR = {Albert, A. A.},
TITLE = {Finite division algebras and finite
planes},
BOOKTITLE = {Combinatorial analysis},
EDITOR = {Bellman, Richard E. and Hall, Jr., Marshall},
SERIES = {Proceedings of Symposia in Applied Mathematics},
NUMBER = {10},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1960},
PAGES = {53--70},
NOTE = {(Columbia University, New York, April
24--26, 1958). MR:22 \#6831. Zbl:0096.15003.},
}
A. A. Albert :
“Generalized twisted fields ,”
Pac. J. Math.
11 : 1
(1961 ),
pp. 1–8 .
MR
0122850
Zbl
0154.27203
article
BibTeX
@article {key0122850m,
AUTHOR = {Albert, A. A.},
TITLE = {Generalized twisted fields},
JOURNAL = {Pac. J. Math.},
FJOURNAL = {Pacific Journal of Mathematics},
VOLUME = {11},
NUMBER = {1},
YEAR = {1961},
PAGES = {1--8},
URL = {http://projecteuclid.org/euclid.pjm/1103037530},
NOTE = {MR:23 \#A182. Zbl:0154.27203.},
ISSN = {0030-8730},
}
A. A. Albert :
Structure of algebras ,
7th edition.
AMS Colloquium Publications 24 .
American Mathematical Society (Providence, RI ),
1961 .
Revised printing.
MR
0123587
book
BibTeX
@book {key0123587m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Structure of algebras},
EDITION = {7th},
SERIES = {AMS Colloquium Publications},
NUMBER = {24},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1961},
PAGES = {xi+210},
NOTE = {Revised printing. MR:23 \#A912.},
}
A. A. Albert :
“Isotopy for generalized twisted fields ,”
Anais Acad. Brasil. Ci.
33
(1961 ),
pp. 265–275 .
MR
0139639
Zbl
0154.27301
article
BibTeX
@article {key0139639m,
AUTHOR = {Albert, A. A.},
TITLE = {Isotopy for generalized twisted fields},
JOURNAL = {Anais Acad. Brasil. Ci.},
FJOURNAL = {Anais da Academia Brasileira de Ci\^encias},
VOLUME = {33},
YEAR = {1961},
PAGES = {265--275},
NOTE = {MR:25 \#3070. Zbl:0154.27301.},
ISSN = {0001-3765},
}
A. A. Albert :
“Finite planes for the high school ,”
Math. Teach.
55 : 3
(March 1962 ),
pp. 165–169 .
An address given in connection with the Thirty-ninth Annual Meeting of the National Council of Teachers of Mathematics, Chicago, 7 April, 1961.
article
BibTeX
@article {key98276880,
AUTHOR = {Albert, A. A.},
TITLE = {Finite planes for the high school},
JOURNAL = {Math. Teach.},
FJOURNAL = {The Mathematics Teacher},
VOLUME = {55},
NUMBER = {3},
MONTH = {March},
YEAR = {1962},
PAGES = {165--169},
URL = {http://www.jstor.org/stable/27956559},
NOTE = {An address given in connection with
the Thirty-ninth Annual Meeting of the
National Council of Teachers of Mathematics,
Chicago, 7 April, 1961.},
ISSN = {0025-5769},
}
A. A. Albert :
“On the nuclei of a simple Jordan algebra ,”
Proc. Nat. Acad. Sci. U.S.A.
50 : 3
(1963 ),
pp. 446–447 .
MR
0153718
Zbl
0115.02702
article
Abstract
BibTeX
@article {key0153718m,
AUTHOR = {Albert, A. A.},
TITLE = {On the nuclei of a simple {J}ordan algebra},
JOURNAL = {Proc. Nat. Acad. Sci. U.S.A.},
FJOURNAL = {Proceedings of the National Academy
of Sciences of the United States of
America},
VOLUME = {50},
NUMBER = {3},
YEAR = {1963},
PAGES = {446--447},
DOI = {10.1073/pnas.50.3.446},
NOTE = {MR:27 \#3679. Zbl:0115.02702.},
ISSN = {0027-8424},
}
A. A. Albert :
“On involutorial associative division algebras ,”
Scripta Math.
26
(1963 ),
pp. 309–316 .
MR
0179202
Zbl
0147.28702
article
BibTeX
@article {key0179202m,
AUTHOR = {Albert, A. A.},
TITLE = {On involutorial associative division
algebras},
JOURNAL = {Scripta Math.},
FJOURNAL = {Scripta Mathematica},
VOLUME = {26},
YEAR = {1963},
PAGES = {309--316},
NOTE = {MR:31 \#3451. Zbl:0147.28702.},
ISSN = {0036-9713},
}
Studies in modern algebra .
Edited by A. A. Albert .
MAA Studies in Mathematics 2 .
Prentice-Hall (Englewood Cliffs, NJ ),
1963 .
MR
0146228
Zbl
0192.00102
book
BibTeX
@book {key0146228m,
TITLE = {Studies in modern algebra},
EDITOR = {Albert, A. A.},
SERIES = {MAA Studies in Mathematics},
NUMBER = {2},
PUBLISHER = {Prentice-Hall},
ADDRESS = {Englewood Cliffs, NJ},
YEAR = {1963},
PAGES = {vii+190},
NOTE = {MR:0146228. Zbl:0192.00102.},
}
A. A. Albert :
“On associative division algebras of prime degree ,”
Proc. Am. Math. Soc.
16
(1965 ),
pp. 799–802 .
MR
0179203
Zbl
0135.07402
article
Abstract
BibTeX
In 1938 Richard Brauer showed that, if \( \mathfrak{D} \) is an associative division algebra of degree five over its center \( \mathfrak{F} \) , there is a field \( \mathfrak{K} \) of degree at most twelve over \( \mathfrak{F} \) such that the scalar extension \( \mathfrak{D}\times\mathfrak{K} \) is a cyclic algebra over \( \mathfrak{K} \) . Indeed
\[ \mathfrak{K}=\mathfrak{F}(\alpha_1,\alpha_2,\alpha_3) ,\]
where \( \alpha_1 \) is a root of a quadratic equation over \( \mathfrak{F} \) , \( \alpha_2 \) is a root of a quadratic equation over \( \mathfrak{F}(\alpha_1) \) , and \( \alpha_3 \) is a root of a cubic equation over \( \mathfrak{F}(\alpha_1,\alpha_2) \) . Since that time there has been no progress in the study of the structure of associative central division algebras of prime degree.
In view of Brauer’s result it seems reasonable, as a first step in the study of central division algebras \( \mathfrak{D} \) of prime degree \( p \) over \( \mathfrak{F} \) , to consider the case where there is a quadratic field \( \mathfrak{K} \) over \( \mathfrak{F} \) such that \( \mathfrak{D}_{\mathfrak{K}} \) is cyclic. Then
\[ \mathfrak{D}_{\mathfrak{K}}=\mathfrak{D}\times\mathfrak{K} \]
has a subfield \( \mathfrak{Z} \) which is cyclic of degree \( p \) over \( \mathfrak{F} \) . The simplest subcase is that where \( \mathfrak{Z} \) is actually normal, but, of course, not cyclic over \( \mathfrak{F} \) . We shall treat this case under the assumption that \( \mathfrak{F} \) has characteristic \( p \) , and shall prove that then \( \mathfrak{D} \) is a cyclic algebra over \( \mathfrak{F} \) .
@article {key0179203m,
AUTHOR = {Albert, A. A.},
TITLE = {On associative division algebras of
prime degree},
JOURNAL = {Proc. Am. Math. Soc.},
FJOURNAL = {Proceedings of the American Mathematical
Society},
VOLUME = {16},
YEAR = {1965},
PAGES = {799--802},
DOI = {10.2307/2033926},
NOTE = {MR:31 \#3452. Zbl:0135.07402.},
ISSN = {0002-9939},
}
A. A. Albert :
“A normal form for Riemann matrices ,”
Canad. J. Math.
17
(1965 ),
pp. 1025–1029 .
MR
0182628
Zbl
0196.30104
article
BibTeX
@article {key0182628m,
AUTHOR = {Albert, A. A.},
TITLE = {A normal form for {R}iemann matrices},
JOURNAL = {Canad. J. Math.},
FJOURNAL = {Canadian Journal of Mathematics. Journal
Canadien de Math\'ematiques},
VOLUME = {17},
YEAR = {1965},
PAGES = {1025--1029},
DOI = {10.4153/CJM-1965-097-0},
NOTE = {MR:32 \#111. Zbl:0196.30104.},
ISSN = {0008-414X},
}
A. A. Albert :
“On exceptional Jordan division algebras ,”
Pac. J. Math.
15 : 2
(1965 ),
pp. 377–404 .
MR
0182647
Zbl
0135.07202
article
Abstract
BibTeX
In 1957 the author gave a construction of a class, of central simple exceptional Jordan algebras \( \mathfrak{H} \) , over any field \( \mathfrak{F} \) of characteristic not two, called cyclic Jordan algebras. The principal ingredients of this construction were the following:
A cyclic cubic field \( \mathfrak{K} \) with generating automorphism \( S \) over \( \mathfrak{F} \) .
A Cayley algebra \( \mathfrak{C} \) , with \( \mathfrak{K} \) as center, so that \( \mathfrak{C} \) has dimension eight over \( \mathfrak{K} \) , and dimension 24 over \( \mathfrak{F} \) .
A nonsingular linear transformation \( T \) over \( \mathfrak{F} \) of \( \mathfrak{C} \) , which induces \( S \) in \( \mathfrak{K} \) , and commutes with the conjugate operation of \( \mathfrak{C} \) .
An element \( g \) in \( \mathfrak{C} \) , and a nonzero element \( \gamma \) of \( \mathfrak{K} \) , such that
\[ g=gT \quad\text{and}\quad g\bar{g} = [\gamma(\gamma S)(\gamma S^2)]^{-1} .\]
Thus \( g \) is nonsingular. Also the polynomial algebra \( \mathfrak{G}=\mathfrak{F}[g] \) is either a quadratic field over \( \mathfrak{F} \) or is the direct sum,
\[ \mathfrak{G}=e_1\mathfrak{F}\oplus e_2\mathfrak{F} ,\]
of two copies \( e_i\mathfrak{F} \) of \( \mathfrak{F} \) .
The properties
\[ [g(xy)T]=[g(xT)](yT) \quad\text{and}\quad xT^3 = g^{-1}xg ,\]
for every \( x \) and \( y \) of \( \mathfrak{C} \) .
In the present paper we shall give a general solution of the equations of (v), and shall determine \( T \) in terms of two parameters in \( \mathfrak{L}=\mathfrak{K}[g] \) satisfying some conditions of an arithmetic type. We shall also provide a special set of values of all of the parameters of our construction, and shall so provide a proof of the existence of cyclic Jordan division algebras with attached Cayley algebra \( \mathfrak{C} \) a division algebra.
The existence of a transformation \( T \) with the two properties of (v) for some element \( g = gT \) , in the Cayley algebra \( \mathfrak{C} \) which satisfies (iv), was demonstrated by the author in the paper [Albert 1958] only in the case where \( \mathfrak{G} \) is not a field, and consequently \( \mathfrak{C} \) is a split algebra. In that case it was proved that cyclic Jordan division algebras do exist, for certain kinds of fields \( \mathfrak{F} \) . Thus the case where \( \mathfrak{G} \) is a field, and \( \mathfrak{C} \) may possibly be a division algebra, remained.
@article {key0182647m,
AUTHOR = {Albert, A. A.},
TITLE = {On exceptional {J}ordan division algebras},
JOURNAL = {Pac. J. Math.},
FJOURNAL = {Pacific Journal of Mathematics},
VOLUME = {15},
NUMBER = {2},
YEAR = {1965},
PAGES = {377--404},
URL = {http://projecteuclid.org/euclid.pjm/1102995794},
NOTE = {MR:32 \#130. Zbl:0135.07202.},
ISSN = {0030-8730},
}
A. A. Albert :
“On some properties of biabelian fields ,”
Anais Acad. Brasil. Ci.
38
(1966 ),
pp. 217–221 .
MR
0207683
Zbl
0154.03903
article
BibTeX
@article {key0207683m,
AUTHOR = {Albert, A. A.},
TITLE = {On some properties of biabelian fields},
JOURNAL = {Anais Acad. Brasil. Ci.},
FJOURNAL = {Anais da Academia Brasileira de Ci\^encias},
VOLUME = {38},
YEAR = {1966},
PAGES = {217--221},
NOTE = {MR:34 \#7498. Zbl:0154.03903.},
ISSN = {0001-3765},
}
A. A. Albert :
“The finite planes of Ostrom ,”
Bol. Soc. Mat. Mex., II. Ser.
11
(1966 ),
pp. 1–13 .
MR
0231271
Zbl
0157.27003
article
BibTeX
@article {key0231271m,
AUTHOR = {Albert, A. A.},
TITLE = {The finite planes of {O}strom},
JOURNAL = {Bol. Soc. Mat. Mex., II. Ser.},
FJOURNAL = {Bolet\'in de la Sociedad Matem\'atica
Mexicana. Segunda Serie},
VOLUME = {11},
YEAR = {1966},
PAGES = {1--13},
NOTE = {MR:37 \#6826. Zbl:0157.27003.},
ISSN = {0037-8615},
}
A. A. Albert :
“Finite fields ,”
Kibern. Sb., Nov. Ser.
3
(1966 ),
pp. 7–49 .
Russian translation of chapter 5 of Fundamental concepts of higher algebra (1956) .
Zbl
0147.01802
article
BibTeX
@article {key0147.01802z,
AUTHOR = {Albert, A. A.},
TITLE = {Finite fields},
JOURNAL = {Kibern. Sb., Nov. Ser.},
FJOURNAL = {Kiberneticheskij Sbornik. Novaya Seriya},
VOLUME = {3},
YEAR = {1966},
PAGES = {7--49},
NOTE = {Russian translation of chapter 5 of
\textit{Fundamental concepts of higher
algebra} (1956). Zbl:0147.01802.},
}
A. A. Albert :
“On certain polynomial systems ,”
Scripta Math.
28
(1967 ),
pp. 15–19 .
MR
0211990
Zbl
0152.02302
article
BibTeX
@article {key0211990m,
AUTHOR = {Albert, A. A.},
TITLE = {On certain polynomial systems},
JOURNAL = {Scripta Math.},
FJOURNAL = {Scripta Mathematica},
VOLUME = {28},
YEAR = {1967},
PAGES = {15--19},
NOTE = {MR:35 \#2865. Zbl:0152.02302.},
ISSN = {0036-9713},
}
A. A. Albert :
“New results on associative division algebras ,”
J. Algebra
5 : 1
(January 1967 ),
pp. 110–132 .
MR
0202757
Zbl
0144.02503
article
Abstract
BibTeX
It is well known that every central division algebra of degree two or three is a cyclic algebra, and that every algebra of degree four is a crossed product. It is also known that there exist noncyclic algebras of degree four. Very little is known about algebras of degree \( n > 4 \) .
The principal question in the theory of associative division algebras is then the question of the existence of algebras which are not crossed products. It is thus natural to discuss algebras of prime degree \( p \) , a case where every crossed product is cyclic.
We shall address ourselves here to a study of the nature of division algebras \( \mathfrak{D} \) of prime degree \( p \) over a field \( \mathfrak{F} \) of characteristic \( p \) , and shall limit our discussion to the case where there exists a quadratic extension \( \mathfrak{K} \) of \( \mathfrak{F} \) such that the extension \( \mathfrak{D}_0 = \mathfrak{D}\times\mathfrak{K} \) is a cyclic algebra .
@article {key0202757m,
AUTHOR = {Albert, A. A.},
TITLE = {New results on associative division
algebras},
JOURNAL = {J. Algebra},
FJOURNAL = {Journal of Algebra},
VOLUME = {5},
NUMBER = {1},
MONTH = {January},
YEAR = {1967},
PAGES = {110--132},
DOI = {10.1016/0021-8693(67)90030-0},
NOTE = {MR:34 \#2617. Zbl:0144.02503.},
ISSN = {0021-8693},
}
A. A. Albert :
“On associative division algebras ,”
Bull. Am. Math. Soc.
74
(1968 ),
pp. 438–454 .
Retiring Presidential Address delivered at the 74th annual meeting of the AMS on January 23, 1967, in San Francisco.
MR
0222114
Zbl
0157.08001
article
Abstract
BibTeX
We shall study the structure of a central division algebra \( \mathfrak{D} \) , of odd prime degree \( p \) over any field \( \mathfrak{F} \) of characteristic \( p \) , which has the property that there exists a quadratic extension field \( \mathfrak{K} \) of \( \mathfrak{F} \) such that the algebra \( \mathfrak{D}_0 = \mathfrak{D}\times\mathfrak{K} \) is cyclic over \( \mathfrak{K} \) . We shall obtain a simplified version of the condition that a cyclic algebra \( \mathfrak{D}_0 \) , of degree \( p \) over \( \mathfrak{K} \) , shall possess the factorization property \( \mathfrak{D}_0 = \mathfrak{D}\times\mathfrak{K} \) . We shall also derive a new sufficient condition that such a \( \mathfrak{D} \) shall be cyclic over \( \mathfrak{F} \) , and shall present a large class of our algebras \( \mathfrak{D}_0 \) which satisfy this condition.
@article {key0222114m,
AUTHOR = {Albert, A. A.},
TITLE = {On associative division algebras},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {74},
YEAR = {1968},
PAGES = {438--454},
DOI = {10.1090/S0002-9904-1968-11963-9},
NOTE = {Retiring Presidential Address delivered
at the 74th annual meeting of the AMS
on January 23, 1967, in San Francisco.
MR:36 \#5166. Zbl:0157.08001.},
ISSN = {0002-9904},
}
A. A. Albert and R. Sandler :
An introduction to finite projective planes .
Holt, Rinehart and Winston (New York ),
1968 .
MR
0227851
Zbl
0194.21502
book
People
BibTeX
@book {key0227851m,
AUTHOR = {Albert, A. Adrian and Sandler, Reuben},
TITLE = {An introduction to finite projective
planes},
PUBLISHER = {Holt, Rinehart and Winston},
ADDRESS = {New York},
YEAR = {1968},
PAGES = {viii+98},
NOTE = {MR:37 \#3435. Zbl:0194.21502.},
}
A. A. Albert :
“A note on certain cyclic algebras ,”
J. Algebra
14 : 1
(September 1970 ),
pp. 70–72 .
MR
0251066
Zbl
0186.06901
article
BibTeX
@article {key0251066m,
AUTHOR = {Albert, A. A.},
TITLE = {A note on certain cyclic algebras},
JOURNAL = {J. Algebra},
FJOURNAL = {Journal of Algebra},
VOLUME = {14},
NUMBER = {1},
MONTH = {September},
YEAR = {1970},
PAGES = {70--72},
DOI = {10.1016/0021-8693(70)90133-X},
NOTE = {MR:40 \#4297. Zbl:0186.06901.},
ISSN = {0021-8693},
}
A. A. Albert :
“Tensor products of quaternion algebras ,”
Proc. Am. Math. Soc.
35 : 1
(September 1972 ),
pp. 65–66 .
MR
0297803
Zbl
0263.16012
article
Abstract
BibTeX
@article {key0297803m,
AUTHOR = {Albert, A. A.},
TITLE = {Tensor products of quaternion algebras},
JOURNAL = {Proc. Am. Math. Soc.},
FJOURNAL = {Proceedings of the American Mathematical
Society},
VOLUME = {35},
NUMBER = {1},
MONTH = {September},
YEAR = {1972},
PAGES = {65--66},
DOI = {10.2307/2038442},
NOTE = {MR:45 \#6855. Zbl:0263.16012.},
ISSN = {0002-9939},
}
Collection of articles dedicated to the memory of Abraham Adrian Albert ,
published as Scripta Math.
29 : 3–4 .
Yeshiva University (New York ),
1973 .
MR
0396137
book
BibTeX
@book {key0396137m,
TITLE = {Collection of articles dedicated to
the memory of {A}braham {A}drian {A}lbert},
PUBLISHER = {Yeshiva University},
ADDRESS = {New York},
YEAR = {1973},
PAGES = {v + 191--483},
NOTE = {Published as \textit{Scripta Math.}
\textbf{29}:3--4. MR:53 \#5.},
ISSN = {0036-9713},
}
I. N. Herstein :
“On a theorem of A. A. Albert ,”
pp. 391–394
in
Collection of articles dedicated to the memory of Abraham Adrian Albert ,
published as Scripta Math.
29 : 3–4
(1973 ).
MR
0435137
Zbl
0266.16014
incollection
People
BibTeX
@article {key0435137m,
AUTHOR = {Herstein, I. N.},
TITLE = {On a theorem of {A}. {A}. {A}lbert},
JOURNAL = {Scripta Math.},
FJOURNAL = {Scripta Mathematica},
VOLUME = {29},
NUMBER = {3--4},
YEAR = {1973},
PAGES = {391--394},
NOTE = {\textit{Collection of articles dedicated
to the memory of Abraham Adrian Albert}.
MR:55 \#8098. Zbl:0266.16014.},
ISSN = {0036-9713},
}
I. N. Herstein :
“A. Adrian Albert ,”
pp. iv–v
in
Collection of articles dedicated to the memory of Abraham Adrian Albert ,
published as Scripta Math.
29 : 3–4
(1973 ).
MR
0403899
incollection
People
BibTeX
@article {key0403899m,
AUTHOR = {Herstein, I. N.},
TITLE = {A. {A}drian {A}lbert},
JOURNAL = {Scripta Math.},
FJOURNAL = {Scripta Mathematica},
VOLUME = {29},
NUMBER = {3--4},
YEAR = {1973},
PAGES = {iv--v},
NOTE = {\textit{Collection of articles dedicated
to the memory of Abraham Adrian Albert}.
MR:53 \#7708.},
ISSN = {0036-9713},
}
D. Zelinsky :
“A. A. Albert ,”
Am. Math. Monthly
80
(1973 ),
pp. 661–665 .
MR
0313017
Zbl
0264.01019
article
People
BibTeX
Read it here
@article {key0313017m,
AUTHOR = {Zelinsky, D.},
TITLE = {A. {A}. {A}lbert},
JOURNAL = {Am. Math. Monthly},
FJOURNAL = {The American Mathematical Monthly},
VOLUME = {80},
YEAR = {1973},
PAGES = {661--665},
DOI = {10.2307/2319167},
NOTE = {MR:47 \#1572. Zbl:0264.01019.},
ISSN = {0002-9890},
}
N. Jacobson :
“Abraham Adrian Albert (1905–1972) ,”
Bull. Am. Math. Soc.
80
(1974 ),
pp. 1075–1100 .
MR
0342341
Zbl
0292.01025
article
People
BibTeX
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@article {key0342341m,
AUTHOR = {Jacobson, Nathan},
TITLE = {Abraham {A}drian {A}lbert (1905--1972)},
JOURNAL = {Bull. Am. Math. Soc.},
FJOURNAL = {Bulletin of the American Mathematical
Society},
VOLUME = {80},
YEAR = {1974},
PAGES = {1075--1100},
DOI = {10.1090/S0002-9904-1974-13622-0},
NOTE = {MR:49 \#7087. Zbl:0292.01025.},
ISSN = {0002-9904},
}
L. E. Dickson :
The collected mathematical papers of Leonard Eugene Dickson ,
vol. 3 .
Edited by A. A. Albert .
Chelsea Publishing Co. (New York ),
1975 .
MR
0441667
book
People
BibTeX
@book {key0441667m,
AUTHOR = {Dickson, Leonard Eugene},
TITLE = {The collected mathematical papers of
{L}eonard {E}ugene {D}ickson},
VOLUME = {3},
PUBLISHER = {Chelsea Publishing Co.},
ADDRESS = {New York},
YEAR = {1975},
PAGES = {580},
NOTE = {Edited by A. A. Albert.
MR:0441667.},
ISBN = {9780828403061},
}
L. E. Dickson :
The collected mathematical papers of Leonard Eugene Dickson ,
vol. 5 .
Edited by A. A. Albert .
Chelsea Publishing Co. (New York ),
1975 .
MR
0441669
book
People
BibTeX
@book {key0441669m,
AUTHOR = {Dickson, Leonard Eugene},
TITLE = {The collected mathematical papers of
{L}eonard {E}ugene {D}ickson},
VOLUME = {5},
PUBLISHER = {Chelsea Publishing Co.},
ADDRESS = {New York},
YEAR = {1975},
PAGES = {644},
NOTE = {Edited by A. A. Albert.
MR:0441669.},
ISBN = {9780828403061},
}
L. E. Dickson :
The collected mathematical papers of Leonard Eugene Dickson ,
vol. 4 .
Edited by A. A. Albert .
Chelsea Publishing Co. (New York ),
1975 .
MR
0441668
book
People
BibTeX
@book {key0441668m,
AUTHOR = {Dickson, Leonard Eugene},
TITLE = {The collected mathematical papers of
{L}eonard {E}ugene {D}ickson},
VOLUME = {4},
PUBLISHER = {Chelsea Publishing Co.},
ADDRESS = {New York},
YEAR = {1975},
PAGES = {636},
NOTE = {Edited by A. A. Albert.
MR:0441668.},
ISBN = {9780828403061},
}
L. E. Dickson :
The collected mathematical papers of Leonard Eugene Dickson ,
vol. 1 .
Edited by A. A. Albert .
Chelsea Publishing Co. (New York ),
1975 .
MR
0441665
book
People
BibTeX
@book {key0441665m,
AUTHOR = {Dickson, Leonard Eugene},
TITLE = {The collected mathematical papers of
{L}eonard {E}ugene {D}ickson},
VOLUME = {1},
PUBLISHER = {Chelsea Publishing Co.},
ADDRESS = {New York},
YEAR = {1975},
PAGES = {xvii+680},
NOTE = {Edited by A. A. Albert.
MR:0441665.},
ISBN = {9780828403061},
}
L. E. Dickson :
The collected mathematical papers of Leonard Eugene Dickson ,
vol. 2 .
Edited by A. A. Albert .
Chelsea Publishing Co. (New York ),
1975 .
MR
0441666
book
People
BibTeX
@book {key0441666m,
AUTHOR = {Dickson, Leonard Eugene},
TITLE = {The collected mathematical papers of
{L}eonard {E}ugene {D}ickson},
VOLUME = {2},
PUBLISHER = {Chelsea Publishing Co.},
ADDRESS = {New York},
YEAR = {1975},
PAGES = {766},
NOTE = {Edited by A. A. Albert.
MR:0441666.},
ISBN = {9780828403061},
}
L. E. Dickson :
The collected mathematical papers of Leonard Eugene Dickson ,
vol. 6 .
Edited by A. A. Albert .
Chelsea Publishing Co. (New York ),
1983 .
MR
749229
book
People
BibTeX
@book {key749229m,
AUTHOR = {Dickson, Leonard Eugene},
TITLE = {The collected mathematical papers of
{L}eonard {E}ugene {D}ickson},
VOLUME = {6},
PUBLISHER = {Chelsea Publishing Co.},
ADDRESS = {New York},
YEAR = {1983},
PAGES = {714},
NOTE = {Edited by A. A. Albert.
MR:749229.},
ISBN = {9780828403061},
}
I. Kaplansky :
“Abraham Adrian Albert: November 9, 1905–June 6, 1972 ,”
pp. 244–264
in
A century of mathematics in America ,
part I .
Edited by P. Duren, R. A. Askey, and U. C. Merzbach .
History of Mathematics 1 .
American Mathematical Society (Providence, RI ),
1988 .
MR
1003173
Zbl
0667.01014
incollection
People
BibTeX
Read it here
@incollection {key1003173m,
AUTHOR = {Kaplansky, Irving},
TITLE = {Abraham {A}drian {A}lbert: {N}ovember
9, 1905--{J}une 6, 1972},
BOOKTITLE = {A century of mathematics in {A}merica},
EDITOR = {Duren, Peter and Askey, Richard A. and
Merzbach, Uta C.},
VOLUME = {I},
SERIES = {History of Mathematics},
NUMBER = {1},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1988},
PAGES = {244--264},
NOTE = {MR:91a:01041. Zbl:0667.01014.},
ISBN = {9780821801246},
}
A. A. Albert :
Collected mathematical papers ,
part 2: Nonassociative algebras and miscellany .
Edited by R. E. Block, N. Jacobson, J. M. Osborn, D. J. Saltman, and D. Zelinsky .
Collected Works 3.2 .
American Mathematical Society (Providence, RI ),
1993 .
With a preface by the editors and Irving Kaplansky. With biographies of Albert by Zelinsky, Jacobson, Kaplansky and Israel N. Herstein.
MR
1213452
Zbl
0790.01040
book
People
BibTeX
@book {key1213452m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Collected mathematical papers},
VOLUME = {2: {N}onassociative algebras and miscellany},
SERIES = {Collected Works},
NUMBER = {3.2},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1993},
PAGES = {lxxviii+938},
NOTE = {Edited by R. E. Block, N. Jacobson,
J. M. Osborn, D. J. Saltman,
and D. Zelinsky. With
a preface by the editors and Irving
Kaplansky. With biographies of Albert
by Zelinsky, Jacobson, Kaplansky and
Israel N. Herstein. MR:94f:01047b. Zbl:0790.01040.},
ISBN = {9780821800072},
}
A. A. Albert :
Collected mathematical papers ,
part 1: Associative algebras and Riemann matrices .
Edited by R. E. Block, N. Jacobson, J. M. Osborn, D. J. Saltman, and D. Zelinsky .
Collected Works 3.1 .
American Mathematical Society (Providence, RI ),
1993 .
With a preface by the editors and Irving Kaplansky. With biographies of Albert by Zelinsky, Jacobson, Kaplansky and Israel N. Herstein.
MR
1213451
Zbl
0790.01039
book
People
BibTeX
@book {key1213451m,
AUTHOR = {Albert, A. Adrian},
TITLE = {Collected mathematical papers},
VOLUME = {1: {A}ssociative algebras and {R}iemann
matrices},
SERIES = {Collected Works},
NUMBER = {3.1},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {1993},
PAGES = {lxxviii+743},
NOTE = {Edited by R. E. Block, N. Jacobson,
J. M. Osborn, D. J. Saltman,
and D. Zelinsky. With
a preface by the editors and Irving
Kaplansky. With biographies of Albert
by Zelinsky, Jacobson, Kaplansky and
Israel N. Herstein. MR:94f:01047a. Zbl:0790.01039.},
ISBN = {9780821800058},
}
N. E. Albert :
A\( ^3 \) & his algebra: How a boy from Chicago’s west side became a force in American mathematics .
iUniverse (Lincoln, NE ),
2005 .
With a preface by Erwin Kleinfeld.
MR
2147379
Zbl
1069.01006
book
People
BibTeX
@book {key2147379m,
AUTHOR = {Albert, Nancy E.},
TITLE = {A\$^3\$ \& his algebra: {H}ow a boy from
Chicago's west side became a force in
American mathematics},
PUBLISHER = {iUniverse},
ADDRESS = {Lincoln, NE},
YEAR = {2005},
PAGES = {xiv+351},
NOTE = {With a preface by Erwin Kleinfeld. MR:2005m:01024.
Zbl:1069.01006.},
ISBN = {9780595328178, 0595328172},
}
D. D. Fenster and J. Schwermer :
“A delicate collaboration: Adrian Albert and Helmut Hasse and the principal theorem in division algebras in the early 1930s ,”
Arch. Hist. Exact Sci.
59 : 4
(2005 ),
pp. 349–379 .
MR
2188938
Zbl
1066.01026
article
Abstract
People
BibTeX
Traditionally, the words “collaboration,” and “principal theorem in division algebras in the 1930s” are associated with the celebrated German trio of mathematicians, Richard Brauer, Helmut Hasse and Emmy Noether. In fact, Brauer, Hasse, and Noether formed one of the collaborative efforts that led to the proof of the principal theorem in linear algebras in the 1930s, that is, the structural description of normal division algebras over an algebraic number field. This paper, however, highlights the other joint work linked with the proof of this theorem, namely that of A. Adrian Albert and Hasse. The paper’s title alludes to a tension in this collaboration. It also refers to the delicate rapport Hasse and Albert cultivated in their correspondence. The seemingly cordial friendship they projected on paper helped keep potentially difficult issues in balance and, consequently, preserved their mutual exchanges. Our specific avenue of investigation emphasizes the correspondence from Albert to Hasse in 1931 and early 1932. At that time, Brauer, Hasse and Noether worked to prove the principal theorem in Germany. Ultimately, in late 1931, this triumvirate established the principal theorem that every normal division algebra over an algebraic number field of finite degree is cyclic [Brauer et al. 1932]. Two months later, Albert and Hasse published a joint work with an alternative proof, entitled “A Determination of all Normal Division Algebras Over an Algebraic Number Field” which also included something of a brief history of the theorem [Albert and Hasse 1932].
In the current paper, we use new archival materials to begin to unravel the behind-the-scenes history of this truly international development in the history of mathematics. In the first two sections of this paper we introduce the protagonists of our research: Albert and Hasse. We trace the individual mathematical paths Albert and Hasse each traveled to arrive at the central question in division algebras. In particular, we see the strong influence of Leonard Eugene Dickson and Joseph Henry Maclagan Wedderburn on the mathematical work of Albert and the prominent role of Kurt Hensel’s \( p \) -adic number theory in Hasse’s mathematical researches. A more formal discussion of the mathematical concepts related to the theory of normal simple algebras in the late 1920s and early 1930s forms the focus of the following section. With this framework in place, we turn our attention to the actual correspondence from Albert to Hasse. These letters contribute to a clearer understanding of the development of a proof of the “principal theorem” in the theory of linear algebras in those waning months of 1931 in Germany and Chicago. Finally, we offer some reflective, concluding remarks on this history.
@article {key2188938m,
AUTHOR = {Fenster, Della D. and Schwermer, Joachim},
TITLE = {A delicate collaboration: {A}drian {A}lbert
and {H}elmut {H}asse and the principal
theorem in division algebras in the
early 1930s},
JOURNAL = {Arch. Hist. Exact Sci.},
FJOURNAL = {Archive for History of Exact Sciences},
VOLUME = {59},
NUMBER = {4},
YEAR = {2005},
PAGES = {349--379},
DOI = {10.1007/s00407-004-0093-6},
NOTE = {MR:2006i:01019. Zbl:1066.01026.},
ISSN = {0003-9519},
CODEN = {AHESAN},
}
D. D. Fenster :
“Research in algebra at the University of Chicago: Leonard Eugene Dickson and A. Adrian Albert ,”
pp. 179–197
in
Episodes in the history of modern algebra (1800–1950) .
Edited by J. Gray and K. H. Parshall .
History of Mathematics 32 .
American Mathematical Society (Providence, RI ),
2007 .
MR
2353496
Zbl
1128.01023
incollection
People
BibTeX
@incollection {key2353496m,
AUTHOR = {Fenster, Della Dumbaugh},
TITLE = {Research in algebra at the {U}niversity
of {C}hicago: {L}eonard {E}ugene {D}ickson
and {A}. {A}drian {A}lbert},
BOOKTITLE = {Episodes in the history of modern algebra
(1800--1950)},
EDITOR = {Gray, Jeremy and Parshall, Karen Hunger},
SERIES = {History of Mathematics},
NUMBER = {32},
PUBLISHER = {American Mathematical Society},
ADDRESS = {Providence, RI},
YEAR = {2007},
PAGES = {179--197},
NOTE = {MR:2353496. Zbl:1128.01023.},
ISBN = {9780821843437},
}