In arithmetic geometry, the BombieriāLang conjecture is an unsolved problem conjectured by Enrico Bombieri and Serge Lang about the Zariski density of the set of rational points of an algebraic variety of general type.
Statement
The weak BombieriāLang conjecture for surfaces states that if is a smooth surface of general type defined over a number field , then the -rational points of do not form a dense set in the Zariski topology on . [1]
The general form of the BombieriāLang conjecture states that if is a positive-dimensional algebraic variety of general type defined over a number field , then the -rational points of do not form a dense set in the Zariski topology. [2] [3] [4]
The refined form of the BombieriāLang conjecture states that if is an algebraic variety of general type defined over a number field , then there is a dense open subset of such that for all number field extensions over , the set of -rational points in is finite. [4]
History
The BombieriāLang conjecture was independently posed by Enrico Bombieri and Serge Lang. In a 1980 lecture at the University of Chicago, Enrico Bombieri posed a problem about the degeneracy of rational points for surfaces of general type. [1] Independently in a series of papers starting in 1971, Serge Lang conjectured a more general relation between the distribution of rational points and algebraic hyperbolicity, [1] [5] [6] [7] formulated in the "refined form" of the BombieriāLang conjecture. [4]
Generalizations and implications
The BombieriāLang conjecture is an analogue for surfaces of Faltings's theorem, which states that algebraic curves of genus greater than one only have finitely many rational points. [8]
If true, the BombieriāLang conjecture would resolve the ErdÅsāUlam problem, as it would imply that there do not exist dense subsets of the Euclidean plane all of whose pairwise distances are rational. [8] [9]
In 1997, Lucia Caporaso, Barry Mazur, Joe Harris, and Patricia Pacelli showed that the BombieriāLang conjecture implies a uniform boundedness conjecture for rational points: there is a constant depending only on and such that the number of rational points of any genus curve over any degree number field is at most . [2] [3]
References
- ^ a b c Das, Pranabesh; Turchet, Amos (2015), "Invitation to integral and rational points on curves and surfaces", in Gasbarri, Carlo; Lu, Steven; Roth, Mike; Tschinkel, Yuri (eds.), Rational Points, Rational Curves, and Entire Holomorphic Curves on Projective Varieties, Contemporary Mathematics, vol. 654, American Mathematical Society, pp. 53ā73, arXiv: 1407.7750
- ^ a b Poonen, Bjorn (2012), Uniform boundedness of rational points and preperiodic points, arXiv: 1206.7104
- ^ a b ConceiĆ§Ć£o, Ricardo; Ulmer, Douglas; Voloch, JosĆ© Felipe (2012), "Unboundedness of the number of rational points on curves over function fields", New York Journal of Mathematics, 18: 291ā293
- ^ a b c Hindry, Marc; Silverman, Joseph H. (2000), "F.5.2. The BombieriāLang Conjecture", Diophantine Geometry: An Introduction, Graduate Texts in Mathematics, vol. 201, Springer-Verlag, New York, pp. 479ā482, doi: 10.1007/978-1-4612-1210-2, ISBN 0-387-98975-7, MR 1745599
- ^ Lang, Serge (1971), "Transcendental numbers and diophantine approximations", Bulletin of the American Mathematical Society, vol. 77, no. 5, pp. 635ā678, doi: 10.1090/S0002-9904-1971-12761-1, ISSN 0002-9904
- ^ Lang, Serge (1974), "Higher dimensional diophantine problems", Bulletin of the American Mathematical Society, vol. 80, no. 5, pp. 779ā788, doi: 10.1090/S0002-9904-1974-13516-0, ISSN 0002-9904
- ^ Lang, Serge (1983), Fundamentals of Diophantine geometry, New York: Springer-Verlag, p. 224, ISBN 0-387-90837-4
- ^ a b Tao, Terence (December 20, 2014), "The Erdos-Ulam problem, varieties of general type, and the Bombieri-Lang conjecture", What's new
- ^ Shaffaf, Jafar (May 2018), "A solution of the ErdÅsāUlam problem on rational distance sets assuming the BombieriāLang conjecture", Discrete & Computational Geometry, 60 (8), arXiv: 1501.00159, doi: 10.1007/s00454-018-0003-3
 | This algebraic geometryārelated article is a stub. You can help Wikipedia by expanding it. |
In arithmetic geometry, the BombieriāLang conjecture is an unsolved problem conjectured by Enrico Bombieri and Serge Lang about the Zariski density of the set of rational points of an algebraic variety of general type.
Statement
The weak BombieriāLang conjecture for surfaces states that if is a smooth surface of general type defined over a number field , then the -rational points of do not form a dense set in the Zariski topology on . [1]
The general form of the BombieriāLang conjecture states that if is a positive-dimensional algebraic variety of general type defined over a number field , then the -rational points of do not form a dense set in the Zariski topology. [2] [3] [4]
The refined form of the BombieriāLang conjecture states that if is an algebraic variety of general type defined over a number field , then there is a dense open subset of such that for all number field extensions over , the set of -rational points in is finite. [4]
History
The BombieriāLang conjecture was independently posed by Enrico Bombieri and Serge Lang. In a 1980 lecture at the University of Chicago, Enrico Bombieri posed a problem about the degeneracy of rational points for surfaces of general type. [1] Independently in a series of papers starting in 1971, Serge Lang conjectured a more general relation between the distribution of rational points and algebraic hyperbolicity, [1] [5] [6] [7] formulated in the "refined form" of the BombieriāLang conjecture. [4]
Generalizations and implications
The BombieriāLang conjecture is an analogue for surfaces of Faltings's theorem, which states that algebraic curves of genus greater than one only have finitely many rational points. [8]
If true, the BombieriāLang conjecture would resolve the ErdÅsāUlam problem, as it would imply that there do not exist dense subsets of the Euclidean plane all of whose pairwise distances are rational. [8] [9]
In 1997, Lucia Caporaso, Barry Mazur, Joe Harris, and Patricia Pacelli showed that the BombieriāLang conjecture implies a uniform boundedness conjecture for rational points: there is a constant depending only on and such that the number of rational points of any genus curve over any degree number field is at most . [2] [3]
References
- ^ a b c Das, Pranabesh; Turchet, Amos (2015), "Invitation to integral and rational points on curves and surfaces", in Gasbarri, Carlo; Lu, Steven; Roth, Mike; Tschinkel, Yuri (eds.), Rational Points, Rational Curves, and Entire Holomorphic Curves on Projective Varieties, Contemporary Mathematics, vol. 654, American Mathematical Society, pp. 53ā73, arXiv: 1407.7750
- ^ a b Poonen, Bjorn (2012), Uniform boundedness of rational points and preperiodic points, arXiv: 1206.7104
- ^ a b ConceiĆ§Ć£o, Ricardo; Ulmer, Douglas; Voloch, JosĆ© Felipe (2012), "Unboundedness of the number of rational points on curves over function fields", New York Journal of Mathematics, 18: 291ā293
- ^ a b c Hindry, Marc; Silverman, Joseph H. (2000), "F.5.2. The BombieriāLang Conjecture", Diophantine Geometry: An Introduction, Graduate Texts in Mathematics, vol. 201, Springer-Verlag, New York, pp. 479ā482, doi: 10.1007/978-1-4612-1210-2, ISBN 0-387-98975-7, MR 1745599
- ^ Lang, Serge (1971), "Transcendental numbers and diophantine approximations", Bulletin of the American Mathematical Society, vol. 77, no. 5, pp. 635ā678, doi: 10.1090/S0002-9904-1971-12761-1, ISSN 0002-9904
- ^ Lang, Serge (1974), "Higher dimensional diophantine problems", Bulletin of the American Mathematical Society, vol. 80, no. 5, pp. 779ā788, doi: 10.1090/S0002-9904-1974-13516-0, ISSN 0002-9904
- ^ Lang, Serge (1983), Fundamentals of Diophantine geometry, New York: Springer-Verlag, p. 224, ISBN 0-387-90837-4
- ^ a b Tao, Terence (December 20, 2014), "The Erdos-Ulam problem, varieties of general type, and the Bombieri-Lang conjecture", What's new
- ^ Shaffaf, Jafar (May 2018), "A solution of the ErdÅsāUlam problem on rational distance sets assuming the BombieriāLang conjecture", Discrete & Computational Geometry, 60 (8), arXiv: 1501.00159, doi: 10.1007/s00454-018-0003-3
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