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Stark conjectures

December 15, 2023

In number theory, the Stark conjectures, introduced by Stark (1971, 1975, 1976, 1980) and later expanded by Tate (1984), give conjectural information about the coefficient of the leading term in the Taylor expansion of an Artin L-function associated with a Galois extension K/k of algebraic number fields. The conjectures generalize the analytic class number formula expressing the leading coefficient of the Taylor series for the Dedekind zeta function of a number field as the product of a regulator related to S-units of the field and a rational number.

When K/k is an abelian extension and the order of vanishing of the L-function at s = 0 is one, Stark gave a refinement of his conjecture, predicting the existence of certain S-units, called Stark units, which generate abelian extensions of number fields.

Formulation edit

General case edit

The Stark conjectures, in the most general form, predict that the leading coefficient of an Artin L-function is the product of a type of regulator, the Stark regulator, with an algebraic number.

Abelian rank-one case edit

When the extension is abelian and the order of vanishing of an L-function at s = 0 is one, Stark's refined conjecture predicts the existence of Stark units, whose roots generate Kummer extensions of K that are abelian over the base field k (and not just abelian over K, as Kummer theory implies). As such, this refinement of his conjecture has theoretical implications for solving Hilbert's twelfth problem.

Computation edit

Stark units in the abelian rank-one case have been computed in specific examples, allowing verification of the veracity of his refined conjecture. These also provide an important computational tool for generating abelian extensions of number fields, forming the basis for some standard algorithms for computing abelian extensions of number fields.

The first rank-zero cases are used in recent versions of the PARI/GP computer algebra system to compute Hilbert class fields of totally real number fields, and the conjectures provide one solution to Hilbert's twelfth problem, which challenged mathematicians to show how class fields may be constructed over any number field by the methods of complex analysis.

Progress edit

Stark's principal conjecture has been proven in a few special cases, such as when the character defining the L-function takes on only rational values. Except when the base field is the field of rational numbers or an imaginary quadratic field, which were covered in the work of Stark,[1] the abelian Stark conjectures is still unproved for number fields. More progress has been made in function fields of an algebraic variety.

Manin (2004) related Stark's conjectures to the noncommutative geometry of Alain Connes.[2] This provides a conceptual framework for studying the conjectures, although at the moment it is unclear whether Manin's techniques will yield the actual proof.

Variations edit

In 1980, Benedict Gross formulated the Gross–Stark conjecture, a p-adic analogue of the Stark conjectures relating derivatives of Deligne–Ribet p-adic L-functions (for totally even characters of totally real number fields) to p-units.[3] This was proved conditionally by Henri Darmon, Samit Dasgupta, and Robert Pollack in 2011.[4] The proof was completed and made unconditional by Dasgupta, Mahesh Kakde, and Kevin Ventullo in 2018.[5] A further refinement of the p-adic conjecture was proposed by Gross in 1988.[6]

In 1984, John Tate formulated the Brumer–Stark conjecture, which gives a refinement of the abelian rank-one Stark conjecture at totally split finite primes (for totally complex extensions of totally real base fields). The function field analogue of the Brumer–Stark conjecture was proved by John Tate and Pierre Deligne in 1984.[7][8] In 2023, Dasgupta and Kakde proved the Brumer–Stark conjecture away from the prime 2.[9]

In 1996, Karl Rubin proposed an integral refinement of the Stark conjecture in the abelian case.[10] In 1999, Cristian Dumitru Popescu proposed a function field analogue of Rubin's conjecture and proved it in some cases.[11]

Notes edit

  1. ^ Stark, Harold M. (1980), "L-functions at s = 1. IV. First derivatives at s = 0", Advances in Mathematics, 35 (3): 197–235, doi:10.1016/0001-8708(80)90049-3, ISSN 0001-8708, MR 0563924
  2. ^ Manin, Yu. I.; Panchishkin, A. A. (2007). Introduction to Modern Number Theory. Encyclopaedia of Mathematical Sciences. Vol. 49 (Second ed.). p. 171. ISBN 978-3-540-20364-3. ISSN 0938-0396. Zbl 1079.11002.
  3. ^ Gross, Benedict H. (1982). "p-adic L-series at s=0". Journal of the Faculty of Science, University of Tokyo. 28: 979–994.
  4. ^ Darmon, Henri; Dasgupta, Samit; Pollack, Robert (2011). "Hilbert Modular Forms and the Gross-Stark Conjecture". Annals of Mathematics. 174 (1): 439–484. doi:10.4007/annals.2011.174.1.12.
  5. ^ Dasgupta, Samit; Kakde, Mahesh; Ventullo, Kevin (2018). "On the Gross-Stark Conjecture" (PDF). Annals of Mathematics. 188 (3): 833–870. doi:10.4007/annals.2018.188.3.3.
  6. ^ Gross, Benedict H. (1988). "On the values of abelian L-functions at s=0". Journal of the Faculty of Science, University of Tokyo. 35: 177–197.
  7. ^ Tate, John (1984). Les conjectures de Stark sur les fonctions L d'Artin en s = 0. Progress in Mathematics. Vol. 47. Boston, MA: Birkhäuser.
  8. ^ Rosen, Michael (2002), "15. The Brumer-Stark conjecture", Number theory in function fields, Graduate Texts in Mathematics, vol. 210, New York, NY: Springer-Verlag, ISBN 0-387-95335-3, Zbl 1043.11079
  9. ^ Dasgupta, Samit; Kakde, Mahesh (2023). "On the Brumer-Stark Conjecture and Refinements". Annals of Mathematics. 197 (1): 289–388. doi:10.4007/annals.2023.197.1.5. S2CID 219557526.
  10. ^ Rubin, Karl (1996). "A Stark conjecture "over Z" for abelian L-functions with multiple zeros". Annales de l'Institut Fourier. 46: 33–62. doi:10.5802/aif.1505.
  11. ^ Popescu, Cristian D. (1999). "On a refined Stark conjecture for function fields". Compositio Mathematica. 116 (3): 321–367. doi:10.1023/A:1000833610462. S2CID 15198245.

References edit

  • Burns, David; Sands, Jonathan; Solomon, David, eds. (2004), , Contemporary Mathematics, vol. 358, Providence, RI: American Mathematical Society, doi:10.1090/conm/358, ISBN 978-0-8218-3480-0, MR 2090725, archived from the original on 2012-04-26
  • Manin, Yuri Ivanovich (2004), "Real multiplication and noncommutative geometry (ein Alterstraum)", in Piene, Ragni; Laudal, Olav Arnfinn (eds.), The legacy of Niels Henrik Abel, Berlin, New York: Springer-Verlag, pp. 685–727, arXiv:math/0202109, Bibcode:2002math......2109M, ISBN 978-3-540-43826-7, MR 2077591
  • Popescu, Cristian D. (1999), "On a refined Stark conjecture for function fields", Compositio Mathematica, 116 (3): 321–367, doi:10.1023/A:1000833610462, ISSN 0010-437X, MR 1691163
  • Rubin, Karl (1996), "A Stark conjecture over Z for abelian L-functions with multiple zeros", Annales de l'Institut Fourier, 46 (1): 33–62, doi:10.5802/aif.1505, ISSN 0373-0956, MR 1385509
  • Stark, Harold M. (1971), "Values of L-functions at s = 1. I. L-functions for quadratic forms.", Advances in Mathematics, 7 (3): 301–343, doi:10.1016/S0001-8708(71)80009-9, ISSN 0001-8708, MR 0289429
  • Stark, Harold M. (1975), "L-functions at s = 1. II. Artin L-functions with rational characters", Advances in Mathematics, 17 (1): 60–92, doi:10.1016/0001-8708(75)90087-0, ISSN 0001-8708, MR 0382194
  • Stark, H. M. (1977), "Class fields and modular forms of weight one", in Serre, Jean-Pierre; Zagier, D. B. (eds.), Modular Functions of One Variable V: Proceedings International Conference, University of Bonn, Sonderforschungsbereich Theoretische Mathematik, July 1976, Lecture Notes in Math, vol. 601, Berlin, New York: Springer-Verlag, pp. 277–287, doi:10.1007/BFb0063951, ISBN 978-3-540-08348-1, MR 0450243
  • Stark, Harold M. (1976), "L-functions at s = 1. III. Totally real fields and Hilbert's twelfth problem", Advances in Mathematics, 22 (1): 64–84, doi:10.1016/0001-8708(76)90138-9, ISSN 0001-8708, MR 0437501
  • Stark, Harold M. (1980), "L-functions at s = 1. IV. First derivatives at s = 0", Advances in Mathematics, 35 (3): 197–235, doi:10.1016/0001-8708(80)90049-3, ISSN 0001-8708, MR 0563924
  • Tate, John (1984), "Les conjectures de Stark sur les fonctions L d'Artin en s=0", Mathematical Programming, Progress in Mathematics, Boston, MA: Birkhäuser Boston, 47 (1–3): 143–153, doi:10.1007/BF01580857, ISBN 978-0-8176-3188-8, MR 0782485, S2CID 13291194

External links edit

  • Hayes, David R. (1999), , archived from the original on February 4, 2012{{citation}}: CS1 maint: unfit URL (link)

December 15, 2023
stark, conjectures, number, theory, introduced, stark, 1971, 1975, 1976, 1980, later, expanded, tate, 1984, give, conjectural, information, about, coefficient, leading, term, taylor, expansion, artin, function, associated, with, galois, extension, algebraic, n. In number theory the Stark conjectures introduced by Stark 1971 1975 1976 1980 and later expanded by Tate 1984 give conjectural information about the coefficient of the leading term in the Taylor expansion of an Artin L function associated with a Galois extension K k of algebraic number fields The conjectures generalize the analytic class number formula expressing the leading coefficient of the Taylor series for the Dedekind zeta function of a number field as the product of a regulator related to S units of the field and a rational number When K k is an abelian extension and the order of vanishing of the L function at s 0 is one Stark gave a refinement of his conjecture predicting the existence of certain S units called Stark units which generate abelian extensions of number fields Contents 1 Formulation 1 1 General case 1 2 Abelian rank one case 2 Computation 3 Progress 4 Variations 5 Notes 6 References 7 External linksFormulation editGeneral case edit The Stark conjectures in the most general form predict that the leading coefficient of an Artin L function is the product of a type of regulator the Stark regulator with an algebraic number Abelian rank one case edit When the extension is abelian and the order of vanishing of an L function at s 0 is one Stark s refined conjecture predicts the existence of Stark units whose roots generate Kummer extensions of K that are abelian over the base field k and not just abelian over K as Kummer theory implies As such this refinement of his conjecture has theoretical implications for solving Hilbert s twelfth problem Computation editStark units in the abelian rank one case have been computed in specific examples allowing verification of the veracity of his refined conjecture These also provide an important computational tool for generating abelian extensions of number fields forming the basis for some standard algorithms for computing abelian extensions of number fields The first rank zero cases are used in recent versions of the PARI GP computer algebra system to compute Hilbert class fields of totally real number fields and the conjectures provide one solution to Hilbert s twelfth problem which challenged mathematicians to show how class fields may be constructed over any number field by the methods of complex analysis Progress editStark s principal conjecture has been proven in a few special cases such as when the character defining the L function takes on only rational values Except when the base field is the field of rational numbers or an imaginary quadratic field which were covered in the work of Stark 1 the abelian Stark conjectures is still unproved for number fields More progress has been made in function fields of an algebraic variety Manin 2004 related Stark s conjectures to the noncommutative geometry of Alain Connes 2 This provides a conceptual framework for studying the conjectures although at the moment it is unclear whether Manin s techniques will yield the actual proof Variations editIn 1980 Benedict Gross formulated the Gross Stark conjecture a p adic analogue of the Stark conjectures relating derivatives of Deligne Ribet p adic L functions for totally even characters of totally real number fields to p units 3 This was proved conditionally by Henri Darmon Samit Dasgupta and Robert Pollack in 2011 4 The proof was completed and made unconditional by Dasgupta Mahesh Kakde and Kevin Ventullo in 2018 5 A further refinement of the p adic conjecture was proposed by Gross in 1988 6 In 1984 John Tate formulated the Brumer Stark conjecture which gives a refinement of the abelian rank one Stark conjecture at totally split finite primes for totally complex extensions of totally real base fields The function field analogue of the Brumer Stark conjecture was proved by John Tate and Pierre Deligne in 1984 7 8 In 2023 Dasgupta and Kakde proved the Brumer Stark conjecture away from the prime 2 9 In 1996 Karl Rubin proposed an integral refinement of the Stark conjecture in the abelian case 10 In 1999 Cristian Dumitru Popescu proposed a function field analogue of Rubin s conjecture and proved it in some cases 11 Notes edit Stark Harold M 1980 L functions at s 1 IV First derivatives at s 0 Advances in Mathematics 35 3 197 235 doi 10 1016 0001 8708 80 90049 3 ISSN 0001 8708 MR 0563924 Manin Yu I Panchishkin A A 2007 Introduction to Modern Number Theory Encyclopaedia of Mathematical Sciences Vol 49 Second ed p 171 ISBN 978 3 540 20364 3 ISSN 0938 0396 Zbl 1079 11002 Gross Benedict H 1982 p adic L series at s 0 Journal of the Faculty of Science University of Tokyo 28 979 994 Darmon Henri Dasgupta Samit Pollack Robert 2011 Hilbert Modular Forms and the Gross Stark Conjecture Annals of Mathematics 174 1 439 484 doi 10 4007 annals 2011 174 1 12 Dasgupta Samit Kakde Mahesh Ventullo Kevin 2018 On the Gross Stark Conjecture PDF Annals of Mathematics 188 3 833 870 doi 10 4007 annals 2018 188 3 3 Gross Benedict H 1988 On the values of abelian L functions at s 0 Journal of the Faculty of Science University of Tokyo 35 177 197 Tate John 1984 Les conjectures de Stark sur les fonctionsLd Artin ens 0 Progress in Mathematics Vol 47 Boston MA Birkhauser Rosen Michael 2002 15 The Brumer Stark conjecture Number theory in function fields Graduate Texts in Mathematics vol 210 New York NY Springer Verlag ISBN 0 387 95335 3 Zbl 1043 11079 Dasgupta Samit Kakde Mahesh 2023 On the Brumer Stark Conjecture and Refinements Annals of Mathematics 197 1 289 388 doi 10 4007 annals 2023 197 1 5 S2CID 219557526 Rubin Karl 1996 A Stark conjecture over Z for abelian L functions with multiple zeros Annales de l Institut Fourier 46 33 62 doi 10 5802 aif 1505 Popescu Cristian D 1999 On a refined Stark conjecture for function fields Compositio Mathematica 116 3 321 367 doi 10 1023 A 1000833610462 S2CID 15198245 References editBurns David Sands Jonathan Solomon David eds 2004 Stark s conjectures recent work and new directions Contemporary Mathematics vol 358 Providence RI American Mathematical Society doi 10 1090 conm 358 ISBN 978 0 8218 3480 0 MR 2090725 archived from the original on 2012 04 26 Manin Yuri Ivanovich 2004 Real multiplication and noncommutative geometry ein Alterstraum in Piene Ragni Laudal Olav Arnfinn eds The legacy of Niels Henrik Abel Berlin New York Springer Verlag pp 685 727 arXiv math 0202109 Bibcode 2002math 2109M ISBN 978 3 540 43826 7 MR 2077591 Popescu Cristian D 1999 On a refined Stark conjecture for function fields Compositio Mathematica 116 3 321 367 doi 10 1023 A 1000833610462 ISSN 0010 437X MR 1691163 Rubin Karl 1996 A Stark conjecture over Z for abelian L functions with multiple zeros Annales de l Institut Fourier 46 1 33 62 doi 10 5802 aif 1505 ISSN 0373 0956 MR 1385509 Stark Harold M 1971 Values of L functions at s 1 I L functions for quadratic forms Advances in Mathematics 7 3 301 343 doi 10 1016 S0001 8708 71 80009 9 ISSN 0001 8708 MR 0289429 Stark Harold M 1975 L functions at s 1 II Artin L functions with rational characters Advances in Mathematics 17 1 60 92 doi 10 1016 0001 8708 75 90087 0 ISSN 0001 8708 MR 0382194 Stark H M 1977 Class fields and modular forms of weight one in Serre Jean Pierre Zagier D B eds Modular Functions of One Variable V Proceedings International Conference University of Bonn Sonderforschungsbereich Theoretische Mathematik July 1976 Lecture Notes in Math vol 601 Berlin New York Springer Verlag pp 277 287 doi 10 1007 BFb0063951 ISBN 978 3 540 08348 1 MR 0450243 Stark Harold M 1976 L functions at s 1 III Totally real fields and Hilbert s twelfth problem Advances in Mathematics 22 1 64 84 doi 10 1016 0001 8708 76 90138 9 ISSN 0001 8708 MR 0437501 Stark Harold M 1980 L functions at s 1 IV First derivatives at s 0 Advances in Mathematics 35 3 197 235 doi 10 1016 0001 8708 80 90049 3 ISSN 0001 8708 MR 0563924 Tate John 1984 Les conjectures de Stark sur les fonctions L d Artin en s 0 Mathematical Programming Progress in Mathematics Boston MA Birkhauser Boston 47 1 3 143 153 doi 10 1007 BF01580857 ISBN 978 0 8176 3188 8 MR 0782485 S2CID 13291194External links editHayes David R 1999 Lectures on Stark s Conjectures archived from the original on February 4 2012 a href Template Citation html title Template Citation citation a CS1 maint unfit URL link Retrieved from https en wikipedia org w index php title Stark conjectures amp oldid 1186064792, wikipedia, wiki, book, books, library,

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