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Quadratic Irrationals: An Introduction to Classical Number Theory [Kõva köide]

(University of Graz, Austria)
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Quadratic Irrationals: An Introduction to Classical Number Theory gives a unified treatment of the classical theory of quadratic irrationals. Presenting the material in a modern and elementary algebraic setting, the author focuses on equivalence, continued fractions, quadratic characters, quadratic orders, binary quadratic forms, and class groups.

The book highlights the connection between Gausss theory of binary forms and the arithmetic of quadratic orders. It collects essential results of the theory that have previously been difficult to access and scattered in the literature, including binary quadratic Diophantine equations and explicit continued fractions, biquadratic class group characters, the divisibility of class numbers by 16, F. Mertens proof of Gausss duplication theorem, and a theory of binary quadratic forms that departs from the restriction to fundamental discriminants. The book also proves Dirichlets theorem on primes in arithmetic progressions, covers Dirichlets class number formula, and shows that every primitive binary quadratic form represents infinitely many primes. The necessary fundamentals on algebra and elementary number theory are given in an appendix.

Research on number theory has produced a wealth of interesting and beautiful results yet topics are strewn throughout the literature, the notation is far from being standardized, and a unifying approach to the different aspects is lacking. Covering both classical and recent results, this book unifies the theory of continued fractions, quadratic orders, binary quadratic forms, and class groups based on the concept of a quadratic irrational.

Arvustused

" [ a] successful attempt to present a cohesive treatment of several important topics in classical number theory by first developing a theory of quadratic irrationals and then building on that to show how the other topics reflect different faces of this theory. works best as a monograph for those who are already familiar with some parts of the material covered here and would like to see other approaches. it does include a better selection of numerical examples than is found in most books, and it has a number of applications to other areas such as diophantine equations." Allen Stenger, MAA Reviews, January 2014

"comprehensive text dealing with the theory of binary quadratic forms. one of the main interests of this book is that it gathers a lot of important results which are generally strewn throughout the literature and are quite difficult to access. This text is quite clear and some exercises and examples are scattered throughout the book. I therefore think that it will find many interested readers within the international mathematical community." Olivier Bordellès, Mathematical Reviews Clippings, December 2013

Foreword ix
Introduction and Preface to the Reader xi
Notations xiii
Chapter 1 Quadratic irrationals
1(24)
1.1 Quadratic irrationals, quadratic number fields and discriminants
1(6)
1.2 The modular group
7(9)
1.3 Reduced quadratic irrationals
16(5)
1.4 Two short tables of class numbers
21(4)
Chapter 2 Continued fractions
25(38)
2.1 General theory of continued fractions
25(13)
2.2 Continued fractions of quadratic irrationals I: General theory
38(12)
2.3 Continued fractions of quadratic irrationals II: Special types
50(13)
Chapter 3 Quadratic residues and Gauss sums
63(36)
3.1 Elementary theory of power residues
63(4)
3.2 Gauss and Jacobi sums
67(5)
3.3 The quadratic reciprocity law
72(7)
3.4 Sums of two squares
79(3)
3.5 Kronecker and quadratic symbols
82(17)
Chapter 4 L-series and Dirichlet's prime number theorem
99(16)
4.1 Preliminaries and some elementary cases
99(3)
4.2 Multiplicative functions
102(4)
4.3 Dirichlet L-functions and proof of Dirichlet's theorem
106(6)
4.4 Summation of L-series
112(3)
Chapter 5 Quadratic orders
115(76)
5.1 Lattices and orders in quadratic number fields
115(6)
5.2 Units in quadratic orders
121(8)
5.3 Lattices and (invertible) fractional ideals in quadratic orders
129(3)
5.4 Structure of ideals in quadratic orders
132(8)
5.5 Class groups and class semigroups
140(7)
5.6 Ambiguous ideals and ideal classes
147(13)
5.7 An application: Some binary Diophantine equations
160(14)
5.8 Prime ideals and multiplicative ideal theory
174(5)
5.9 Class groups of quadratic orders
179(12)
Chapter 6 Binary quadratic forms
191(66)
6.1 Elementary definitions and equivalence relations
191(8)
6.2 Representation of integers
199(11)
6.3 Reduction
210(3)
6.4 Composition
213(8)
6.5 Theory of genera
221(19)
6.6 Ternary quadratic forms
240(8)
6.7 Sums of squares
248(9)
Chapter 7 Cubic and biquadratic residues
257(64)
7.1 The cubic Jacobi symbol
257(6)
7.2 The cubic reciprocity law
263(8)
7.3 The biquadratic Jacobi symbol
271(8)
7.4 The biquadratic reciprocity law
279(10)
7.5 Rational biquadratic reciprocity laws
289(17)
7.6 A biquadratic class group character and applications
306(15)
Chapter 8 Class groups
321(38)
8.1 The analytic class number formula
322(10)
8.2 L-functions of quadratic orders
332(8)
8.3 Ambiguous classes and classes of order divisibility by 4
340(5)
8.4 Discriminants with cyclic 2-class group: Divisibility by 8 and 16
345(14)
Appendix A Review of elementary algebra and number theory
359(40)
A.1 Fundamentals of group theory
359(3)
A.2 Fundamentals of ring theory
362(3)
A.3 Elementary arithmetic in Z
365(7)
A.4 Lattices
372(3)
A.5 Finite abelian groups
375(5)
A.6 Prime residue class groups
380(4)
A.7 Roots of unity and characters of finite abelian groups
384(5)
A.8 Factorization in integral domains
389(5)
A.9 Algebraic integers
394(5)
Appendix B Some results from analysis
399(8)
B.1 Notational conventions and results from complex analysis
399(2)
B.2 Further analytic tools
401(6)
Bibliography 407(4)
List of Symbols 411(2)
Subject Index 413
Franz Halter-Koch retired as a professor of mathematics from the University of Graz in 2004. A member of the Austrian Academy of Science, Dr. Halter-Koch is the author/coauthor of roughly 150 scientific articles, author of Ideal Systems: An Introduction to Multiplicative Ideal Theory, and coauthor of Non-Unique Factorizations: Algebraic, Combinatorial and Analytic Theory. His research focuses on elementary and algebraic number theory, non-unique factorizations, and abstract multiplicative ideal theory.