The second edition of a book designed to introduce mathematics students to abstract algebra.
"These two volumes must be regarded as a landmark in algebraical literature. The enormous wealth of material, the depth of treatment, and the masterly exposition render these volumes exceptionally valuable. All courses on algebra, from the second undergraduate year to the specialist studies for doctoral students, can benefit from this authoritative treatise by Professor Jacobson." Walter Ledermann, University of Sussex
Author(s): Nathan Jacobson
Edition: 2
Publisher: W.H. Freeman
Year: 1985
Language: English
Pages: 516
City: New York
Tags: Algebra
Preface xi
Preface to the First Edition xiii
INTRODUCTION: CONCEPTS FROM SET THEORY. THE iNTEGERS 1
0.1 The power set of a set 3
0.2 The Cartesian product set. Maps 4
0.3 Equivalence relations. Factoring a map through an
equivalence relation 10
0.4 The natural numbers 15
0.5 The number system I of integers 19
0.6 Some basic arithmetic facts about Z 22
0.7 A word on cardinal numbers 24
1 MONOIDS AND GROUPS 26
1.1 Monoids of transformations and abstract monoids 28
1.2 Groups of transformations and abstract groups 31
1.3 Isomorphism. Cayley’s theorem 36
1.4 Generalized associativity. Commutativity 39
1.5 Submonoids and subgroups generated by a subset. Cyclic groups 42
1.6 Cycle decomposition of permutations 48
1.7 Orbits. Cosets of a subgroup 51
1.8 Congruences. Quotient monoids and groups 54
1.9 Homomorphisms 58
1.10 Subgroups of a homomorphic image. Two basic isomorphism theorems 64
1.11 Free objects. Generators and relations 67
1.12 Groups acting on sets 71
1.13 Sylow’s theorems 79
2 RINGS 85
2.1 Definition and elementary properties 86
2.2 Types of rings 90
2.3 Matrix rings 92
2.4 Quaternions 98
2.5 Ideals, quotient rings 101
2.6 Ideals and quotient rings for Z 103
2.7 Homomorphisms of rings. Basic theorems 106
2.8 Anti-isomorphisms 111
2.9 Field of fractions of a commutative domain 115
2.10 Polynomial rings 119
2.11 Some properties of polynomial rings and applications 121
2.12 Polynomial functions 134
2.13 Symmetric polynomials 138
2.14 Factorial monoids and rings 140
2.15 Principal ideal domains and Euclidean domains 147
2116 Polynomial extensions of factorial domains 151
2.17 “Rugs” (rings without unit) 155
3 MODULES OVER A PRINCIPAL IDEAL DOMAIN 157
3.1 Ring of endomorphisms of an abelian group 158
3.2 Left and right modules 163
3.3 Fundamental concepts and results 166 .
3.4 Free modules and matrices 170
3.5 Direct sums of modules 175
3.6 Finitely generated modules over a p.i.d. Preliminary results 179
3.7 Equivalence of matrices with entries in a p.i.d. 181
3.8 Structure theorem for finitely generated modules over a p.i.d. 187
3.9 Torsion modules, primary components, invariance theorem 189
3.10 Applications to abelian groups and to linear transformations 194
3.11 The ring of endomorphisms of a finitely generated module
over a p.i.d. 204
4 GALOIS THEORY OF EOUATIONS 210
4.1 Preliminary results, some old. some new 213
4.2 Construction with straight-edge and compass 216
4.3 Splitting field of a polynomial 224
4.4 Multiple roots 229
4.5 The Galois group. The fundamental Galois pairing 234
4.6 Some results on finite groups 244
4.7 Galois criterion for solvability by radicals 251
4.8 The Galois group as permutation group of the roots 256
4.9 The general equation of the nth degree 262
4.10 Equations with rational coeificients and symrhetric group as
Galois group 267
4.11 Constructible regular n-gons 271
4.12 Transcendence of e and n. The Lindemann-Weierstrass theorem 277
4.13 Finite fields 287
4.14 special bases for finite dimensional extensions fields 290
4.15 Traces and norms 296
4.16 Mod p reduction 301
5 REAL POLYNOMIAL EQUATIONS AND INEOUALITIES 306
5.1 Ordered fields. Real closed fields 307
5.2 Stunn’s theorem 311
5.3 Formalizaed Euclidean algorithm and Sturm's theorem 316
5.4 Elimination procedures. Resultants 322
5.5 Decision method for an algebraic curve 327
5.6 Tarski’s theorem 335
6 METRIC VECTOR SPACES AND THE CLASSICAL GROUPS 342
6.1 Linear functions and bilinear forms 343
6.2 Alternate forms 349
6.3 Quadratic forms and symmetric bilinear forms 354
6.4 Basic concepts of orthogonal geometry 361
6.5 Witt’s cancellation theorem 367
6.6 The theorem of Cartan-Dieudonné 371
6.7 Structure of the general linear group GLn(F) 37S
6.8 Structure of orthogonal groups 382
6.9 Symplectic geometry. The symplectic group 391
6.10 Orders of orthogonal and symplectic groups over a finite field 398
6.11 Postscript on hermitian forms and unitary geometry 401
7 ALGEBRAS OVER A FIELD 405
7.1 Definition and examples of associative algebras 406
7.2 Exterior algebras. Application to determinants 411
7.3 Regular matrix representations of associative algebras.
Norms and traces 422
7.4 Change of base field. Transitivity of trace and norm 426
7.5 Non-associative algebras. Lie and Jordan algebras 430
7.6 Hurwitz‘ problem. Composition algebras 438
7.7 Frobenius’ and Weddcrburn's theorems on associative
division algebras 451
8 LATTICES AND BOOLEAN ALGEBRAS 455
8.1 Partially ordered sets and lattices 456
8.2 Distributivity and modularity 461
8.3 The theorem of Jordan-Holdeeredekind 466
8.4 The lattice of subspaces of a vector space.
Fundamental theorem of projective geometry 468
8.5 Boolean algebras 474
8.6 The Mobius function of a partially ordered set 480
Appendix 489
index 493