Arithmetic geometry: Difference between revisions

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{{short description|Branch of algebraic geometry focused on problems in number theory}}
{{Short description|Branch of algebraic geometry}}
{{General geometry|branches}}
{{General geometry|branches}}
[[File:Example of a hyperelliptic curve.svg|thumb|The [[Hyperelliptic curve|hyperelliptic curve]] defined by <math>y^2=x(x+1)(x-3)(x+2)(x-2)</math> has only finitely many [[Rational point|rational point]]s (such as the points <math>(-2, 0)</math> and <math>(-1, 0)</math>) by [[Faltings's theorem|Faltings's theorem]].]]
[[File:Example of a hyperelliptic curve.svg|thumb|The [[hyperelliptic curve]] defined by {{math|''y''<sup>2</sup> {{=}} ''x''(''x'' + 1)(''x'' − 3)(''x'' + 2)(''x'' − 2)}} has only finitely many [[Rational point|rational point]]s (such as the points {{math|(−2, 0)}} and {{math|(−1, 0)}}) by Faltings' theorem.]]
 
In mathematics, '''arithmetic geometry''' is roughly the application of techniques from [[Algebraic geometry|algebraic geometry]] to problems in [[Number theory|number theory]].<ref>{{cite web|title=Introduction to Arithmetic Geometry|last=Sutherland|first=Andrew V.|url=https://ocw.mit.edu/courses/mathematics/18-782-introduction-to-arithmetic-geometry-fall-2013/lecture-notes/MIT18_782F13_lec1.pdf|date=September 5, 2013|access-date=22 March 2019}}</ref> Arithmetic geometry is centered around [[Diophantine geometry]], the study of [[Rational point|rational point]]s of [[Algebraic variety|algebraic varieties]].<ref name="Quanta">{{cite web|url=https://www.quantamagazine.org/peter-scholze-and-the-future-of-arithmetic-geometry-20160628/|title=Peter Scholze and the Future of Arithmetic Geometry|last=Klarreich|first=Erica|date=June 28, 2016|access-date=March 22, 2019}}</ref><ref name="poonen-notes">{{cite web|title=Introduction to Arithmetic Geometry|last=Poonen|first=Bjorn|url=http://math.mit.edu/~poonen/782/782notes.pdf|year=2009|access-date=March 22, 2019}}</ref>
In mathematics, '''arithmetic geometry''' is roughly the application of techniques from [[Algebraic geometry|algebraic geometry]] to problems in [[Number theory|number theory]].<ref>{{cite web|title=Introduction to Arithmetic Geometry|last=Sutherland|first=Andrew V.|url=https://ocw.mit.edu/courses/mathematics/18-782-introduction-to-arithmetic-geometry-fall-2013/lecture-notes/MIT18_782F13_lec1.pdf|date=September 5, 2013|access-date=22 March 2019}}</ref> Arithmetic geometry is centered around [[Diophantine geometry]], the study of [[Rational point|rational point]]s of [[Algebraic variety|algebraic varieties]].<ref name="Quanta">{{cite web|url=https://www.quantamagazine.org/peter-scholze-and-the-future-of-arithmetic-geometry-20160628/|title=Peter Scholze and the Future of Arithmetic Geometry|last=Klarreich|first=Erica|date=June 28, 2016|access-date=March 22, 2019}}</ref><ref name="poonen-notes">{{cite web|title=Introduction to Arithmetic Geometry|last=Poonen|first=Bjorn|url=http://math.mit.edu/~poonen/782/782notes.pdf|year=2009|access-date=March 22, 2019}}</ref>


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==Overview==
==Overview==
The classical objects of interest in arithmetic geometry are rational points: [[Solution set|sets of solutions]] of a [[System of polynomial equations|system of polynomial equations]] over number fields, [[Finite field|finite field]]s, p-adic fields, or [[Algebraic function field|function field]]s, i.e. [[Field (mathematics)|field]]s that are not algebraically closed excluding the [[Real number|real number]]s. Rational points can be directly characterized by [[Height function|height function]]s which measure their arithmetic complexity.<ref>{{cite book | first=Serge | last=Lang |  title=Survey of Diophantine Geometry | publisher=[[Physics:Springer-Verlag|Springer-Verlag]] | year=1997 | isbn=3-540-61223-8 | zbl=0869.11051 | pages=43–67 }}</ref>
The classical objects of interest in arithmetic geometry are rational points: [[Solution set|sets of solutions]] of a [[System of polynomial equations|system of polynomial equations]] over [[Number field|number field]]s, [[Finite field|finite field]]s, [[p-adic field|{{mvar|p}}-adic fields]], or [[Algebraic function field|function field]]s, i.e. [[Field (mathematics)|field]]s that are not algebraically closed excluding the [[Real number|real number]]s. Rational points can be directly characterized by [[Height function|height function]]s which measure their arithmetic complexity.<ref>{{cite book | first=Serge | last=Lang |  title=Survey of Diophantine Geometry | publisher=[[Physics:Springer-Verlag|Springer-Verlag]] | year=1997 | isbn=3-540-61223-8 | zbl=0869.11051 | pages=43–67 }}</ref>


The structure of algebraic varieties defined over non-algebraically closed fields has become a central area of interest that arose with the modern abstract development of algebraic geometry. Over finite fields, [[Étale cohomology|étale cohomology]] provides [[Topological property|topological invariant]]s associated to algebraic varieties.<ref name="grothendieck-cohomology"/> [[P-adic Hodge theory|p-adic Hodge theory]] gives tools to examine when cohomological properties of varieties over the [[Complex number|complex number]]s extend to those over p-adic fields.<ref>{{cite journal | last=Serre | first=Jean-Pierre |  title=Résumé des cours, 1965–66 | journal=Annuaire du Collège de France | location=Paris | year=1967 | pages=49–58}}</ref>
The structure of algebraic varieties defined over non-algebraically closed fields has become a central area of interest that arose with the modern abstract development of algebraic geometry. Over finite fields, [[Étale cohomology|étale cohomology]] provides [[Topological property|topological invariant]]s associated to algebraic varieties.<ref name="grothendieck-cohomology"/> [[p-adic Hodge theory|{{mvar|p}}-adic Hodge theory]] gives tools to examine when cohomological properties of varieties over the [[Complex number|complex number]]s extend to those over [[p-adic field|{{mvar|p}}-adic fields]].<ref>{{cite journal | last=Serre | first=Jean-Pierre |  title=Résumé des cours, 1965–66 | journal=Annuaire du Collège de France | location=Paris | year=1967 | pages=49–58}}</ref>


==History==
==History==
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In the early 19th century, [[Biography:Carl Friedrich Gauss|Carl Friedrich Gauss]] observed that non-zero [[Integer|integer]] solutions to [[Homogeneous polynomial|homogeneous polynomial]] equations with [[Rational number|rational]] coefficients exist if non-zero rational solutions exist.<ref>{{cite book|title=Diophantine Equations|last=Mordell|first=Louis J.|year=1969|publisher=Academic Press|isbn=978-0125062503|page=1}}</ref>
In the early 19th century, [[Biography:Carl Friedrich Gauss|Carl Friedrich Gauss]] observed that non-zero [[Integer|integer]] solutions to [[Homogeneous polynomial|homogeneous polynomial]] equations with [[Rational number|rational]] coefficients exist if non-zero rational solutions exist.<ref>{{cite book|title=Diophantine Equations|last=Mordell|first=Louis J.|year=1969|publisher=Academic Press|isbn=978-0125062503|page=1}}</ref>


In the 1850s, [[Biography:Leopold Kronecker|Leopold Kronecker]] formulated the [[Kronecker–Weber theorem]], introduced the theory of [[Divisor (algebraic geometry)|divisor]]s, and made numerous other connections between number theory and [[Algebra|algebra]]. He then conjectured his "liebster Jugendtraum" ("dearest dream of youth"), a generalization that was later put forward by Hilbert in a modified form as his [[Hilbert's problems|twelfth problem]], which outlines a goal to have number theory operate only with rings that are quotients of [[Polynomial ring|polynomial ring]]s over the integers.<ref name="Princeton">{{cite book| last1 = Gowers| first1 = Timothy| last2 = Barrow-Green| first2 = June| last3 = Leader| first3 = Imre| title = The Princeton companion to mathematics| url = https://archive.org/details/princetoncompanio00gowe| year = 2008| publisher = Princeton University Press| isbn = 978-0-691-11880-2| pages = 773–774 }}</ref>
In the 1850s, [[Biography:Leopold Kronecker|Leopold Kronecker]] formulated the [[Kronecker–Weber theorem]], introduced the theory of [[Divisor (algebraic geometry)|divisor]]s, and made numerous other connections between number theory and [[Algebra|algebra]]. He then conjectured his "liebster Jugendtraum" ("dearest dream of youth"), a generalization that was later put forward by Hilbert in a modified form as his [[Hilbert's problems|twelfth problem]], which outlines a goal to have number theory operate only with rings that are quotients of [[Polynomial ring|polynomial ring]]s over the integers.<ref name="Princeton">{{cite book| last1 = Gowers| first1 = Timothy| last2 = Barrow-Green| first2 = June| last3 = Leader| first3 = Imre| title = The Princeton Companion to Mathematics| url = https://archive.org/details/princetoncompanio00gowe| year = 2008| publisher = Princeton University Press| isbn = 978-0-691-11880-2| pages = 773–774 }}</ref>


===Early-to-mid 20th century: algebraic developments and the Weil conjectures===
===Early-to-mid 20th century: algebraic developments and the Weil conjectures===
In the late 1920s, [[Biography:André Weil|André Weil]] demonstrated profound connections between algebraic geometry and number theory with his doctoral work leading to the [[Mordell–Weil theorem]] which demonstrates that the set of rational points of an [[Abelian variety|abelian variety]] is a [[Finitely generated abelian group|finitely generated abelian group]].<ref>A. Weil, ''L'arithmétique sur les courbes algébriques'', Acta Math 52, (1929) p.&nbsp;281-315, reprinted in vol 1 of his collected papers {{isbn|0-387-90330-5}}.</ref>
In the late 1920s, [[Biography:André Weil|André Weil]] demonstrated profound connections between algebraic geometry and number theory with his doctoral work leading to the [[Mordell–Weil theorem]] which demonstrates that the set of rational points of an [[Abelian variety|abelian variety]] is a [[Finitely generated abelian group|finitely generated abelian group]].<ref>{{cite journal|first=A. |last=Weil |title=L'arithmétique sur les courbes algébriques |journal=Acta Mathematica |volume=52 |date=1929 |pages=281–315}}. Reprinted in Volume 1 of his collected papers, {{isbn|0-387-90330-5}}.</ref>


Modern foundations of algebraic geometry were developed based on contemporary [[Commutative algebra|commutative algebra]], including valuation theory and the theory of [[Ideal (ring theory)|ideals]] by [[Biography:Oscar Zariski|Oscar Zariski]] and others in the 1930s and 1940s.<ref>{{cite book | last1=Zariski | first1=Oscar |  editor1-last=Abhyankar | editor1-first=Shreeram S. | editor1-link=Shreeram Shankar Abhyankar| editor2-last=Lipman | editor2-first=Joseph | editor2-link=Joseph Lipman| editor3-last=Mumford | editor3-first=David | editor3-link=David Mumford | title=Algebraic surfaces | orig-year=1935 | url=https://books.google.com/books?id=d6Zzhm9eCmgC | publisher=[[Physics:Springer-Verlag|Springer-Verlag]] | location=Berlin, New York | edition=second supplemented | series=Classics in mathematics | isbn=978-3-540-58658-6 | year=2004 | mr=0469915}}</ref>
Modern foundations of algebraic geometry were developed based on contemporary [[Commutative algebra|commutative algebra]], including valuation theory and the theory of [[Ideal (ring theory)|ideals]] by [[Biography:Oscar Zariski|Oscar Zariski]] and others in the 1930s and 1940s.<ref>{{cite book | last1=Zariski | first1=Oscar |  editor1-last=Abhyankar | editor1-first=Shreeram S. | editor1-link=Shreeram Shankar Abhyankar| editor2-last=Lipman | editor2-first=Joseph | editor2-link=Joseph Lipman| editor3-last=Mumford | editor3-first=David | editor3-link=David Mumford | title=Algebraic Surfaces | orig-year=1935 | url=https://books.google.com/books?id=d6Zzhm9eCmgC | publisher=[[Physics:Springer-Verlag|Springer-Verlag]] | location=Berlin, New York | edition=2nd suppl. | series=Classics in Mathematics | isbn=978-3-540-58658-6 | year=2004 | mr=0469915}}</ref>


In 1949, [[Biography:André Weil|André Weil]] posed the landmark [[Weil conjectures]] about the [[Local zeta-function|local zeta-function]]s of algebraic varieties over finite fields.<ref>{{cite journal | last1=Weil | first1=André |  title=Numbers of solutions of equations in finite fields | doi=10.1090/S0002-9904-1949-09219-4  | mr=0029393 | year=1949 | journal=[[Organization:Bulletin of the American Mathematical Society|Bulletin of the American Mathematical Society]] | issn=0002-9904 | volume=55 | pages=497–508 | issue=5| doi-access=free }} Reprinted in Oeuvres Scientifiques/Collected Papers by André Weil {{isbn|0-387-90330-5}}</ref> These conjectures offered a framework between algebraic geometry and number theory that propelled [[Biography:Alexander Grothendieck|Alexander Grothendieck]] to recast the foundations making use of sheaf theory (together with [[Biography:Jean-Pierre Serre|Jean-Pierre Serre]]), and later scheme theory, in the 1950s and 1960s.<ref>{{cite journal | last1 = Serre | first1 = Jean-Pierre | year = 1955 | title = Faisceaux Algebriques Coherents | journal = The Annals of Mathematics | volume = 61 | issue = 2| pages = 197–278 | doi=10.2307/1969915| jstor = 1969915 }}</ref> [[Biography:Bernard Dwork|Bernard Dwork]] proved one of the four Weil conjectures (rationality of the local zeta function) in 1960.<ref>{{cite journal | last1=Dwork | first1=Bernard | author1-link=Bernard Dwork | title=On the rationality of the zeta function of an algebraic variety | jstor=2372974 | mr=0140494 | year=1960 | journal=[[American Journal of Mathematics]] | issn=0002-9327 | volume=82 | pages=631–648 | doi=10.2307/2372974 | issue=3 | publisher=American Journal of Mathematics, Vol. 82, No. 3}}</ref> Grothendieck developed étale cohomology theory to prove two of the Weil conjectures (together with [[Biography:Michael Artin|Michael Artin]] and [[Biography:Jean-Louis Verdier|Jean-Louis Verdier]]) by 1965.<ref name="grothendieck-cohomology">{{cite book | last1=Grothendieck | first1=Alexander | author1-link=Alexander Grothendieck | title=Proc. Internat. Congress Math. (Edinburgh, 1958) | publisher={{wipe|Cambridge University Press}} | mr=0130879 | year=1960 | chapter=The cohomology theory of abstract algebraic varieties | pages=103–118|chapter-url=http://grothendieckcircle.org/}}</ref><ref>{{cite book | last1=Grothendieck | first1=Alexander | author1-link=Alexander Grothendieck | title=Séminaire Bourbaki | chapter-url=http://www.numdam.org/item?id=SB_1964-1966__9__41_0 | publisher=Société Mathématique de France | location=Paris | mr=1608788 | year=1995 | volume=9 | chapter=Formule de Lefschetz et rationalité des fonctions L | pages=41–55|orig-year=1965 |ref= {{harvid|Grothendieck|1965}} }}</ref> The last of the Weil conjectures (an analogue of the [[Riemann hypothesis]]) would be finally proven in 1974 by [[Biography:Pierre Deligne|Pierre Deligne]].<ref>{{cite journal | last1=Deligne | first1=Pierre | author1-link=Pierre Deligne | title=La conjecture de Weil. I | url=http://www.numdam.org/item?id=PMIHES_1974__43__273_0 | mr=0340258 | year=1974 | journal=[[Publications Mathématiques de l'IHÉS]] | volume=43 | issn=1618-1913 | issue=1 | pages=273–307| doi=10.1007/BF02684373 }}</ref>
In 1949, [[Biography:André Weil|André Weil]] posed the landmark [[Weil conjectures]] about the [[Local zeta-function|local zeta-function]]s of algebraic varieties over finite fields.<ref>{{cite journal | last1=Weil | first1=André |  title=Numbers of solutions of equations in finite fields | doi=10.1090/S0002-9904-1949-09219-4  | mr=0029393 | year=1949 | journal=[[Organization:Bulletin of the American Mathematical Society|Bulletin of the American Mathematical Society]] | issn=0002-9904 | volume=55 | pages=497–508 | issue=5| doi-access=free }} Reprinted in Oeuvres Scientifiques/Collected Papers by André Weil {{isbn|0-387-90330-5}}</ref> These conjectures offered a framework between algebraic geometry and number theory that propelled [[Biography:Alexander Grothendieck|Alexander Grothendieck]] to recast the foundations making use of [[Sheaf theory|sheaf theory]] (together with [[Biography:Jean-Pierre Serre|Jean-Pierre Serre]]), and later scheme theory, in the 1950s and 1960s.<ref>{{cite journal | last1 = Serre | first1 = Jean-Pierre | year = 1955 | title = Faisceaux Algébriques Cohérents | journal = The Annals of Mathematics | volume = 61 | issue = 2| pages = 197–278 | doi=10.2307/1969915| jstor = 1969915 }}</ref> [[Biography:Bernard Dwork|Bernard Dwork]] proved one of the four Weil conjectures (rationality of the local zeta function) in 1960.<ref>{{cite journal | last1=Dwork | first1=Bernard | author1-link=Bernard Dwork | title=On the rationality of the zeta function of an algebraic variety | jstor=2372974 | mr=0140494 | year=1960 | journal=[[American Journal of Mathematics]] | issn=0002-9327 | volume=82 | issue=3 | pages=631–648 | doi=10.2307/2372974 }}</ref> Grothendieck developed étale cohomology theory to prove two of the Weil conjectures (together with [[Biography:Michael Artin|Michael Artin]] and [[Biography:Jean-Louis Verdier|Jean-Louis Verdier]]) by 1965.<ref name="grothendieck-cohomology">{{cite book | last1=Grothendieck | first1=Alexander | author1-link=Alexander Grothendieck | title=Proceedings of the International Congress of Mathematicians (Edinburgh, 1958) | publisher=Cambridge University Press | mr=0130879 | year=1960 | chapter=The cohomology theory of abstract algebraic varieties | pages=103–118|chapter-url=http://grothendieckcircle.org/}}</ref><ref>{{cite book | last1=Grothendieck | first1=Alexander | author1-link=Alexander Grothendieck | title=Séminaire Bourbaki | chapter-url=http://www.numdam.org/item?id=SB_1964-1966__9__41_0 | publisher=Société Mathématique de France | location=Paris | mr=1608788 | year=1995 | volume=9 | chapter=Formule de Lefschetz et rationalité des fonctions L | pages=41–55|orig-year=1965 |ref= {{harvid|Grothendieck|1965}} }}</ref> The last of the Weil conjectures (an analogue of the [[Riemann hypothesis]]) would be finally proven in 1974 by [[Biography:Pierre Deligne|Pierre Deligne]].<ref>{{cite journal | last1=Deligne | first1=Pierre | author1-link=Pierre Deligne | title=La conjecture de Weil. I | url=http://www.numdam.org/item?id=PMIHES_1974__43__273_0 | mr=0340258 | year=1974 | journal=[[Publications Mathématiques de l'IHÉS]] | volume=43 | issn=1618-1913 | issue=1 | pages=273–307| doi=10.1007/BF02684373 | url-access=subscription }}</ref>


===Mid-to-late 20th century: developments in modularity, p-adic methods, and beyond===
===Mid-to-late 20th century: developments in modularity, ''{{mvar|p}}''-adic methods, and beyond===
Between 1956 and 1957, [[Biography:Yutaka Taniyama|Yutaka Taniyama]] and [[Biography:Goro Shimura|Goro Shimura]] posed the [[Modularity theorem|Taniyama–Shimura conjecture]] (now known as the modularity theorem) relating elliptic curves to modular forms.<ref>{{cite journal|last=Taniyama|first=Yutaka |journal=Sugaku|volume=7|page=269|year=1956|title=Problem 12|language=ja}}</ref><ref>{{cite journal | last1=Shimura | first1=Goro | title=Yutaka Taniyama and his time. Very personal recollections | doi=10.1112/blms/21.2.186 | mr=976064 | year=1989 | journal=The Bulletin of the London Mathematical Society | issn=0024-6093 | volume=21 | issue=2 | pages=186–196| doi-access=free }}</ref> This connection would ultimately lead to [[Wiles's proof of Fermat's Last Theorem|the first proof]] of [[Fermat's Last Theorem]] in number theory through algebraic geometry techniques of [[Lift (mathematics)|modularity lifting]] developed by [[Biography:Andrew Wiles|Andrew Wiles]] in 1995.<ref name="wiles1995">{{cite journal|last=Wiles|first=Andrew|year=1995|title=Modular elliptic curves and Fermat's Last Theorem|url=http://math.stanford.edu/~lekheng/flt/wiles.pdf|journal=Annals of Mathematics|volume=141|issue=3|pages=443–551|oclc=37032255|doi=10.2307/2118559|jstor=2118559|citeseerx=10.1.1.169.9076|access-date=2019-03-22|archive-date=2011-05-10|archive-url=https://web.archive.org/web/20110510062158/http://math.stanford.edu/%7Elekheng/flt/wiles.pdf|url-status=dead}}</ref>
Between 1956 and 1957, [[Biography:Yutaka Taniyama|Yutaka Taniyama]] and [[Biography:Goro Shimura|Goro Shimura]] posed the [[Modularity theorem|Taniyama–Shimura conjecture]] (now known as the modularity theorem) relating elliptic curves to modular forms.<ref>{{cite journal|last=Taniyama|first=Yutaka |journal=Sugaku|volume=7|page=269|year=1956|title=Problem 12|language=ja}}</ref><ref>{{cite journal | last1=Shimura | first1=Goro | title=Yutaka Taniyama and his time. Very personal recollections | doi=10.1112/blms/21.2.186 | mr=976064 | year=1989 | journal=The Bulletin of the London Mathematical Society | issn=0024-6093 | volume=21 | issue=2 | pages=186–196| doi-access=free }}</ref> This connection would ultimately lead to [[Wiles's proof of Fermat's Last Theorem|the first proof]] of [[Fermat's Last Theorem]] in number theory through algebraic geometry techniques of [[Lift (mathematics)|modularity lifting]] developed by [[Biography:Andrew Wiles|Andrew Wiles]] in 1995.<ref name="wiles1995">{{cite journal|last=Wiles|first=Andrew|year=1995|title=Modular elliptic curves and Fermat's Last Theorem|url=http://math.stanford.edu/~lekheng/flt/wiles.pdf|journal=Annals of Mathematics|volume=141|issue=3|pages=443–551|oclc=37032255|doi=10.2307/2118559|jstor=2118559|citeseerx=10.1.1.169.9076|access-date=2019-03-22|archive-date=2011-05-10|archive-url=https://web.archive.org/web/20110510062158/http://math.stanford.edu/%7Elekheng/flt/wiles.pdf|url-status=dead}}</ref>


In the 1960s, Goro Shimura introduced [[Shimura variety|Shimura varieties]] as generalizations of [[Modular curve|modular curve]]s.<ref>{{cite book|last=Shimura|first=Goro|title=The Collected Works of Goro Shimura|publisher=Springer Nature|isbn=978-0387954158|year=2003}}</ref> Since the 1979, Shimura varieties have played a crucial role in the [[Langlands program]] as a natural realm of examples for testing conjectures.<ref>{{cite book|title=Automorphic Forms, Representations, and L-Functions: Symposium in Pure Mathematics|publisher=Chelsea Publishing Company|editor-last1=Borel|editor-first1=Armand|editor-last2=Casselman|editor-first2=William|editor-link2=Bill Casselman (mathematician)|year=1979|volume=XXXIII Part 1|last=Langlands|first=Robert|chapter-url=http://www.sunsite.ubc.ca/DigitalMathArchive/Langlands/pdf/autoreps-ps.pdf|chapter=Automorphic Representations, Shimura Varieties, and Motives. Ein Märchen|pages=205–246}}</ref>
In the 1960s, Goro Shimura introduced [[Shimura variety|Shimura varieties]] as generalizations of [[Modular curve|modular curve]]s.<ref>{{cite book|last=Shimura|first=Goro|title=The Collected Works of Goro Shimura|publisher=Springer Nature|isbn=978-0387954158|year=2003}}</ref> Since the 1979, Shimura varieties have played a crucial role in the [[Langlands program]] as a natural realm of examples for testing conjectures.<ref>{{cite book|title=Automorphic Forms, Representations, and ''L''-Functions: Symposium in Pure Mathematics|publisher=Chelsea Publishing Company|editor-last1=Borel|editor-first1=Armand|editor-last2=Casselman|editor-first2=William|editor-link2=Bill Casselman (mathematician)|year=1979|volume=33 Part 1|last=Langlands|first=Robert|chapter-url=http://www.sunsite.ubc.ca/DigitalMathArchive/Langlands/pdf/autoreps-ps.pdf|chapter=Automorphic Representations, Shimura Varieties, and Motives. Ein Märchen|pages=205–246}}</ref>


In papers in 1977 and 1978, [[Biography:Barry Mazur|Barry Mazur]] proved the [[Torsion conjecture|torsion conjecture]] giving a complete list of the possible torsion subgroups of elliptic curves over the rational numbers. Mazur's first proof of this theorem depended upon a complete analysis of the rational points on certain [[Modular curve|modular curve]]s.<ref>{{cite journal|last=Mazur|first=Barry|title=Modular curves and the Eisenstein ideal|volume=47|issue=1|pages=33–186|year=1977|doi=10.1007/BF02684339|mr=0488287|journal=[[Publications Mathématiques de l'IHÉS]]|url=http://www.numdam.org/item/PMIHES_1977__47__33_0/}}</ref><ref>{{cite journal|last=Mazur|first=Barry|title=Rational isogenies of prime degree|volume=44|issue=2|pages=129–162|year=1978|doi=10.1007/BF01390348|mr=0482230|journal=[[Inventiones Mathematicae]]|others=with appendix by Dorian Goldfeld|bibcode=1978InMat..44..129M}}</ref> In 1996, the proof of the torsion conjecture was extended to all number fields by [[Biography:Loïc Merel|Loïc Merel]].<ref>{{cite journal | last1=Merel | first1=Loïc |  title=Bornes pour la torsion des courbes elliptiques sur les corps de nombres | trans-title=Bounds for the torsion of elliptic curves over number fields | language=fr | doi=10.1007/s002220050059 |mr=1369424 | year=1996 | journal=[[Inventiones Mathematicae]] | volume=124 | issue=1 | pages=437–449 | bibcode=1996InMat.124..437M }}</ref>
In papers in 1977 and 1978, [[Biography:Barry Mazur|Barry Mazur]] proved the [[Torsion conjecture|torsion conjecture]] giving a complete list of the possible torsion subgroups of elliptic curves over the rational numbers. Mazur's first proof of this theorem depended upon a complete analysis of the rational points on certain [[Modular curve|modular curve]]s.<ref>{{cite journal|last=Mazur|first=Barry|title=Modular curves and the Eisenstein ideal|volume=47|issue=1|pages=33–186|year=1977|doi=10.1007/BF02684339|mr=0488287|journal=[[Publications Mathématiques de l'IHÉS]]|url=http://www.numdam.org/item/PMIHES_1977__47__33_0/}}</ref><ref>{{cite journal|last=Mazur|first=Barry|title=Rational isogenies of prime degree|volume=44|issue=2|pages=129–162|year=1978|doi=10.1007/BF01390348|mr=0482230|journal=[[Inventiones Mathematicae]]|others=with appendix by Dorian Goldfeld|bibcode=1978InMat..44..129M}}</ref> In 1996, the proof of the torsion conjecture was extended to all number fields by [[Biography:Loïc Merel|Loïc Merel]].<ref>{{cite journal | last1=Merel | first1=Loïc |  title=Bornes pour la torsion des courbes elliptiques sur les corps de nombres | trans-title=Bounds for the torsion of elliptic curves over number fields | language=fr | doi=10.1007/s002220050059 |mr=1369424 | year=1996 | journal=[[Inventiones Mathematicae]] | volume=124 | issue=1 | pages=437–449 | bibcode=1996InMat.124..437M }}</ref>


In 1983, [[Biography:Gerd Faltings|Gerd Faltings]] proved the [[Faltings's theorem|Mordell conjecture]], demonstrating that a curve of genus greater than 1 has only finitely many rational points (where the Mordell–Weil theorem only demonstrates [[Finitely generated abelian group|finite generation]] of the set of rational points as opposed to finiteness).<ref>{{cite journal | last=Faltings |first=Gerd |year=1983 |title=Endlichkeitssätze für abelsche Varietäten über Zahlkörpern |journal=[[Inventiones Mathematicae]] |volume=73 |issue=3 |pages=349–366 |doi=10.1007/BF01388432 | mr=0718935 | trans-title=Finiteness theorems for abelian varieties over number fields | language=de | bibcode=1983InMat..73..349F}}</ref><ref>{{cite journal |last=Faltings |first=Gerd |year=1984 |title=Erratum: Endlichkeitssätze für abelsche Varietäten über Zahlkörpern |journal=[[Inventiones Mathematicae]] |volume=75 |issue=2 |pages=381 |doi=10.1007/BF01388572 | mr=0732554 | language=de |doi-access=free }}</ref>
In 1983, [[Biography:Gerd Faltings|Gerd Faltings]] proved the Mordell conjecture, demonstrating that a curve of genus greater than 1 has only finitely many rational points (where the Mordell–Weil theorem only demonstrates [[Finitely generated abelian group|finite generation]] of the set of rational points as opposed to finiteness).<ref>{{cite journal | last=Faltings |first=Gerd |year=1983 |title=Endlichkeitssätze für abelsche Varietäten über Zahlkörpern |journal=[[Inventiones Mathematicae]] |volume=73 |issue=3 |pages=349–366 |doi=10.1007/BF01388432 | mr=0718935 | trans-title=Finiteness theorems for abelian varieties over number fields | language=de | bibcode=1983InMat..73..349F}}</ref><ref>{{cite journal |last=Faltings |first=Gerd |year=1984 |title=Erratum: Endlichkeitssätze für abelsche Varietäten über Zahlkörpern |journal=[[Inventiones Mathematicae]] |volume=75 |issue=2 |pages=381 |doi=10.1007/BF01388572 | mr=0732554 | language=de |doi-access=free }}</ref>


In 2001, the proof of the [[Local Langlands conjectures#Local Langlands conjectures for GLn|local Langlands conjectures for GL<sub>n</sub>]] was based on the geometry of certain Shimura varieties.<ref>{{cite book |  last1=Harris | first1=Michael |  last2=Taylor | first2=Richard | title=The geometry and cohomology of some simple Shimura varieties | url=https://books.google.com/books?id=sigBbO69hvMC | publisher=Princeton University Press | series=Annals of Mathematics Studies | isbn=978-0-691-09090-0 | mr=1876802 | year=2001 | volume=151}}</ref>
=== Early 21st century ===
In 2001, the proof of the [[Local Langlands conjectures#Local Langlands conjectures for GLn|local Langlands conjectures for {{math|GL<sub>''n''</sub>}}]] was based on the geometry of certain Shimura varieties.<ref>{{cite book |  last1=Harris | first1=Michael |  last2=Taylor | first2=Richard | title=The geometry and cohomology of some simple Shimura varieties | url=https://books.google.com/books?id=sigBbO69hvMC | publisher=[[Princeton University Press]] | series=Annals of Mathematics Studies | isbn=978-0-691-09090-0 | mr=1876802 | year=2001 | volume=151}}</ref>


In the 2010s, [[Biography:Peter Scholze|Peter Scholze]] developed [[Perfectoid space|perfectoid space]]s and new cohomology theories in arithmetic geometry over p-adic fields with application to Galois representations and certain cases of the weight-monodromy conjecture.<ref>{{cite web |title=Fields Medals 2018 |url=https://www.mathunion.org/imu-awards/fields-medal/fields-medals-2018 |publisher=[[Organization:International Mathematical Union|International Mathematical Union]] |access-date=2 August 2018}}</ref><ref>{{cite web|last=Scholze|first=Peter|url=http://www.math.uni-bonn.de/people/scholze/CDM.pdf|title=Perfectoid spaces: A survey|website=University of Bonn|access-date=4 November 2018}}</ref>
In the 2010s, [[Biography:Peter Scholze|Peter Scholze]] developed [[Perfectoid space|perfectoid space]]s and new cohomology theories in arithmetic geometry over {{mvar|p}}-adic fields with application to Galois representations and certain cases of the weight-monodromy conjecture.<ref>{{cite web |title=Fields Medals 2018 |url=https://www.mathunion.org/imu-awards/fields-medal/fields-medals-2018 |publisher=[[Organization:International Mathematical Union|International Mathematical Union]] |access-date=2 August 2018}}</ref><ref>{{cite web|last=Scholze|first=Peter|url=http://www.math.uni-bonn.de/people/scholze/CDM.pdf|title=Perfectoid spaces: A survey|publisher=University of Bonn|access-date=4 November 2018}}</ref>


==See also==
==See also==
*[[Arithmetic dynamics]]
* [[Anabelian geometry]]
*[[Arithmetic of abelian varieties]]
* [[Arithmetic dynamics]]
*[[Birch and Swinnerton-Dyer conjecture]]
* [[Arithmetic of abelian varieties]]
*[[Moduli of algebraic curves]]
* [[Birch and Swinnerton-Dyer conjecture]]
*[[Siegel modular variety]]
* [[Category theory]]
*[[Siegel's theorem on integral points]]
* [[Frobenioid]]
*[[Category theory]]
* [[Moduli of algebraic curves]]
*[[Frobenioid]]
* [[Siegel modular variety]]
* [[Siegel's theorem on integral points]]


==References==
==References==
{{reflist}}
{{Reflist}}


{{Number theory |expanded}}
{{Number theory |expanded}}
{{Areas of mathematics | state=collapsed}}
{{Areas of mathematics | state=collapsed}}


{{DEFAULTSORT:Arithmetic Geometry}}
{{DEFAULTSORT:Arithmetic Geometry}}
[[Category:Arithmetic geometry| ]]
[[Category:Arithmetic geometry| ]]
[[Category:Fields of mathematics]]


{{Sourceattribution|Arithmetic geometry}}
{{Sourceattribution|Arithmetic geometry}}

Latest revision as of 22:12, 23 May 2026

Short description: Branch of algebraic geometry
Geometry
Projecting a sphere to a plane.
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Dimension
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One-dimensional
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The hyperelliptic curve defined by y2 = x(x + 1)(x − 3)(x + 2)(x − 2) has only finitely many rational points (such as the points (−2, 0) and (−1, 0)) by Faltings' theorem.

In mathematics, arithmetic geometry is roughly the application of techniques from algebraic geometry to problems in number theory.[1] Arithmetic geometry is centered around Diophantine geometry, the study of rational points of algebraic varieties.[2][3]

In more abstract terms, arithmetic geometry can be defined as the study of schemes of finite type over the spectrum of the ring of integers.[4]

Overview

The classical objects of interest in arithmetic geometry are rational points: sets of solutions of a system of polynomial equations over number fields, finite fields, p-adic fields, or function fields, i.e. fields that are not algebraically closed excluding the real numbers. Rational points can be directly characterized by height functions which measure their arithmetic complexity.[5]

The structure of algebraic varieties defined over non-algebraically closed fields has become a central area of interest that arose with the modern abstract development of algebraic geometry. Over finite fields, étale cohomology provides topological invariants associated to algebraic varieties.[6] p-adic Hodge theory gives tools to examine when cohomological properties of varieties over the complex numbers extend to those over p-adic fields.[7]

History

19th century: early arithmetic geometry

In the early 19th century, Carl Friedrich Gauss observed that non-zero integer solutions to homogeneous polynomial equations with rational coefficients exist if non-zero rational solutions exist.[8]

In the 1850s, Leopold Kronecker formulated the Kronecker–Weber theorem, introduced the theory of divisors, and made numerous other connections between number theory and algebra. He then conjectured his "liebster Jugendtraum" ("dearest dream of youth"), a generalization that was later put forward by Hilbert in a modified form as his twelfth problem, which outlines a goal to have number theory operate only with rings that are quotients of polynomial rings over the integers.[9]

Early-to-mid 20th century: algebraic developments and the Weil conjectures

In the late 1920s, André Weil demonstrated profound connections between algebraic geometry and number theory with his doctoral work leading to the Mordell–Weil theorem which demonstrates that the set of rational points of an abelian variety is a finitely generated abelian group.[10]

Modern foundations of algebraic geometry were developed based on contemporary commutative algebra, including valuation theory and the theory of ideals by Oscar Zariski and others in the 1930s and 1940s.[11]

In 1949, André Weil posed the landmark Weil conjectures about the local zeta-functions of algebraic varieties over finite fields.[12] These conjectures offered a framework between algebraic geometry and number theory that propelled Alexander Grothendieck to recast the foundations making use of sheaf theory (together with Jean-Pierre Serre), and later scheme theory, in the 1950s and 1960s.[13] Bernard Dwork proved one of the four Weil conjectures (rationality of the local zeta function) in 1960.[14] Grothendieck developed étale cohomology theory to prove two of the Weil conjectures (together with Michael Artin and Jean-Louis Verdier) by 1965.[6][15] The last of the Weil conjectures (an analogue of the Riemann hypothesis) would be finally proven in 1974 by Pierre Deligne.[16]

Mid-to-late 20th century: developments in modularity, p-adic methods, and beyond

Between 1956 and 1957, Yutaka Taniyama and Goro Shimura posed the Taniyama–Shimura conjecture (now known as the modularity theorem) relating elliptic curves to modular forms.[17][18] This connection would ultimately lead to the first proof of Fermat's Last Theorem in number theory through algebraic geometry techniques of modularity lifting developed by Andrew Wiles in 1995.[19]

In the 1960s, Goro Shimura introduced Shimura varieties as generalizations of modular curves.[20] Since the 1979, Shimura varieties have played a crucial role in the Langlands program as a natural realm of examples for testing conjectures.[21]

In papers in 1977 and 1978, Barry Mazur proved the torsion conjecture giving a complete list of the possible torsion subgroups of elliptic curves over the rational numbers. Mazur's first proof of this theorem depended upon a complete analysis of the rational points on certain modular curves.[22][23] In 1996, the proof of the torsion conjecture was extended to all number fields by Loïc Merel.[24]

In 1983, Gerd Faltings proved the Mordell conjecture, demonstrating that a curve of genus greater than 1 has only finitely many rational points (where the Mordell–Weil theorem only demonstrates finite generation of the set of rational points as opposed to finiteness).[25][26]

Early 21st century

In 2001, the proof of the local Langlands conjectures for GLn was based on the geometry of certain Shimura varieties.[27]

In the 2010s, Peter Scholze developed perfectoid spaces and new cohomology theories in arithmetic geometry over p-adic fields with application to Galois representations and certain cases of the weight-monodromy conjecture.[28][29]

See also

References

  1. Sutherland, Andrew V. (September 5, 2013). "Introduction to Arithmetic Geometry". https://ocw.mit.edu/courses/mathematics/18-782-introduction-to-arithmetic-geometry-fall-2013/lecture-notes/MIT18_782F13_lec1.pdf. 
  2. Klarreich, Erica (June 28, 2016). "Peter Scholze and the Future of Arithmetic Geometry". https://www.quantamagazine.org/peter-scholze-and-the-future-of-arithmetic-geometry-20160628/. 
  3. Poonen, Bjorn (2009). "Introduction to Arithmetic Geometry". http://math.mit.edu/~poonen/782/782notes.pdf. 
  4. Arithmetic geometry in nLab
  5. Lang, Serge (1997). Survey of Diophantine Geometry. Springer-Verlag. pp. 43–67. ISBN 3-540-61223-8. 
  6. 6.0 6.1 Grothendieck, Alexander (1960). "The cohomology theory of abstract algebraic varieties". Proceedings of the International Congress of Mathematicians (Edinburgh, 1958). Cambridge University Press. pp. 103–118. http://grothendieckcircle.org/. 
  7. Serre, Jean-Pierre (1967). "Résumé des cours, 1965–66". Annuaire du Collège de France (Paris): 49–58. 
  8. Mordell, Louis J. (1969). Diophantine Equations. Academic Press. p. 1. ISBN 978-0125062503. 
  9. Gowers, Timothy; Barrow-Green, June; Leader, Imre (2008). The Princeton Companion to Mathematics. Princeton University Press. pp. 773–774. ISBN 978-0-691-11880-2. https://archive.org/details/princetoncompanio00gowe. 
  10. Weil, A. (1929). "L'arithmétique sur les courbes algébriques". Acta Mathematica 52: 281–315. . Reprinted in Volume 1 of his collected papers, ISBN 0-387-90330-5.
  11. Zariski, Oscar (2004). Abhyankar, Shreeram S.; Lipman, Joseph; Mumford, David. eds. Algebraic Surfaces. Classics in Mathematics (2nd suppl. ed.). Berlin, New York: Springer-Verlag. ISBN 978-3-540-58658-6. https://books.google.com/books?id=d6Zzhm9eCmgC. 
  12. Weil, André (1949). "Numbers of solutions of equations in finite fields". Bulletin of the American Mathematical Society 55 (5): 497–508. doi:10.1090/S0002-9904-1949-09219-4. ISSN 0002-9904.  Reprinted in Oeuvres Scientifiques/Collected Papers by André Weil ISBN 0-387-90330-5
  13. Serre, Jean-Pierre (1955). "Faisceaux Algébriques Cohérents". The Annals of Mathematics 61 (2): 197–278. doi:10.2307/1969915. 
  14. Dwork, Bernard (1960). "On the rationality of the zeta function of an algebraic variety". American Journal of Mathematics 82 (3): 631–648. doi:10.2307/2372974. ISSN 0002-9327. 
  15. Grothendieck, Alexander (1995). "Formule de Lefschetz et rationalité des fonctions L". Séminaire Bourbaki. 9. Paris: Société Mathématique de France. pp. 41–55. http://www.numdam.org/item?id=SB_1964-1966__9__41_0. 
  16. Deligne, Pierre (1974). "La conjecture de Weil. I". Publications Mathématiques de l'IHÉS 43 (1): 273–307. doi:10.1007/BF02684373. ISSN 1618-1913. http://www.numdam.org/item?id=PMIHES_1974__43__273_0. 
  17. Taniyama, Yutaka (1956). "Problem 12" (in ja). Sugaku 7: 269. 
  18. Shimura, Goro (1989). "Yutaka Taniyama and his time. Very personal recollections". The Bulletin of the London Mathematical Society 21 (2): 186–196. doi:10.1112/blms/21.2.186. ISSN 0024-6093. 
  19. Wiles, Andrew (1995). "Modular elliptic curves and Fermat's Last Theorem". Annals of Mathematics 141 (3): 443–551. doi:10.2307/2118559. OCLC 37032255. http://math.stanford.edu/~lekheng/flt/wiles.pdf. Retrieved 2019-03-22. 
  20. Shimura, Goro (2003). The Collected Works of Goro Shimura. Springer Nature. ISBN 978-0387954158. 
  21. Langlands, Robert (1979). "Automorphic Representations, Shimura Varieties, and Motives. Ein Märchen". Automorphic Forms, Representations, and L-Functions: Symposium in Pure Mathematics. 33 Part 1. Chelsea Publishing Company. pp. 205–246. http://www.sunsite.ubc.ca/DigitalMathArchive/Langlands/pdf/autoreps-ps.pdf. 
  22. Mazur, Barry (1977). "Modular curves and the Eisenstein ideal". Publications Mathématiques de l'IHÉS 47 (1): 33–186. doi:10.1007/BF02684339. http://www.numdam.org/item/PMIHES_1977__47__33_0/. 
  23. Mazur, Barry (1978). with appendix by Dorian Goldfeld. "Rational isogenies of prime degree". Inventiones Mathematicae 44 (2): 129–162. doi:10.1007/BF01390348. Bibcode1978InMat..44..129M. 
  24. Merel, Loïc (1996). "Bornes pour la torsion des courbes elliptiques sur les corps de nombres" (in fr). Inventiones Mathematicae 124 (1): 437–449. doi:10.1007/s002220050059. Bibcode1996InMat.124..437M. 
  25. Faltings, Gerd (1983). "Endlichkeitssätze für abelsche Varietäten über Zahlkörpern" (in de). Inventiones Mathematicae 73 (3): 349–366. doi:10.1007/BF01388432. Bibcode1983InMat..73..349F. 
  26. Faltings, Gerd (1984). "Erratum: Endlichkeitssätze für abelsche Varietäten über Zahlkörpern" (in de). Inventiones Mathematicae 75 (2): 381. doi:10.1007/BF01388572. 
  27. Harris, Michael; Taylor, Richard (2001). The geometry and cohomology of some simple Shimura varieties. Annals of Mathematics Studies. 151. Princeton University Press. ISBN 978-0-691-09090-0. https://books.google.com/books?id=sigBbO69hvMC. 
  28. "Fields Medals 2018". International Mathematical Union. https://www.mathunion.org/imu-awards/fields-medal/fields-medals-2018. 
  29. Scholze, Peter. "Perfectoid spaces: A survey". University of Bonn. http://www.math.uni-bonn.de/people/scholze/CDM.pdf. 



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