Geometric methods for improving the upper bounds on the number of rational points on algebraic curves over finite fields
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Publication:6471063
arXivmath/0104247MaRDI QIDQ6471063
Kristin Lauter, Jean-Pierre Serre
Publication date: 25 April 2001
Abstract: Currently, the best upper bounds on the number of rational points on an absolutely irreducible, smooth, projective algebraic curve of genus g defined over a finite field F_q come either from Serre's refinement of the Weil bound if the genus is small compared to q, or from Oesterle's optimization of the explicit formulae method if the genus is large. This paper presents three methods for improving these bounds. The arguments used are the indecomposability of the theta divisor of a curve, Galois descent, and Honda-Tate theory. Examples of improvements on the bounds include lowering them for a wide range of small genus when q=2^3, 2^5, 2^{13}, 3^3, 3^5, 5^3, 5^7, and when q=2^{2s}, s>1. For large genera, isolated improvements are obtained for q=3,8,9.
Counting solutions of Diophantine equations (11D45) Abelian varieties of dimension (> 1) (11G10) Arithmetic ground fields for abelian varieties (14K15) Perfectoid spaces and mixed characteristic (14G45)
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