Anabelian geometry
Anabelian geometry is a theory in
Formulation of a conjecture of Grothendieck on curves
The "anabelian question" has been formulated as
How much information about the isomorphism class of the variety X is contained in the knowledge of the étale fundamental group[2]
A concrete example is the case of curves, which may be
- .
Grothendieck conjectured that the algebraic fundamental group G of C, a profinite group, determines C itself (i.e., the isomorphism class of G determines that of C). This was proved by Mochizuki.[3] An example is for the case of (the projective line) and , when the isomorphism class of C is determined by the cross-ratio in K of the four points removed (almost, there being an order to the four points in a cross-ratio, but not in the points removed).[4] There are also results for the case of K a local field.[5]
Mono-anabelian geometry
Shinichi Mochizuki introduced and developed the mono-anabelian geometry, an approach which restores, for a certain class of hyperbolic curves over number fields or some other fields, the curve from its
The opposite approach of mono-anabelian geometry is bi-anabelian geometry, a term coined by Mochizuki in "Topics in Absolute Anabelian Geometry III" to indicate the classical approach.
Mono-anabelian geometry deals with certain types (strictly Belyi type) of hyperbolic curves over number fields and local fields. This theory considerably extends anabelian geometry. Its main aim to construct algorithms which produce the curve, up to an isomorphism, from the étale fundamental group of such a curve. In particular, for the first time this theory produces a simultaneous functorial restoration of the ground number field and its completion, from the fundamental group of a large class of punctured elliptic curves over number fields.[7][8][9] Inter-universal Teichmüller theory of Shinichi Mochizuki is closely connected to and uses various results of mono-anabelian geometry.[10]
Combinatorial anabelian geometry
Shinichi Mochizuki also introduced combinatorial anabelian geometry which deals with issues of hyperbolic curves and other related schemes over algebraically closed fields. The first results were published in Mochizuki's "A combinatorial version of the
Combinatorial anabelian geometry concerns the reconstruction of scheme- or ring-theoretic objects from more primitive combinatorial constituent data. The origin of combinatorial anabelian geometry is in some of such combinatorial ideas in Mochizuki's proofs of the Grothendieck conjecture. Some of the results of combinatorial anabelian geometry provide alternative proofs of partial cases of the Grothendieck conjecture without using p-adic Hodge theory. Combinatorial anabelian geometry helps to study various aspects of the Grothendieck–Teichmüller group and the absolute Galois groups of number fields and mixed-characteristic local fields.[11]
See also
- Class field theory
- Fiber functor
- Neukirch–Uchida theorem
- Belyi's theorem
- Frobenioid
- Inter-universal Teichmüller theory
- p-adic Teichmüller theory
- Langlands correspondences
Notes
- ^ Shinichi Mochizuki, Hiroaka Nakamura, Akio Tamagawa, "The Grothendieck conjecture of the fundamental groups of algebraic curves", Sugaku Exposition (AMS English Translation) (14) 1, American Mathematical Society: 31-53, http://www4.math.sci.osaka-u.ac.jp/~nakamura/zoo/rhino/NTM300.pdf (2001)
- MR 1483109.
- MR 1432110.
- MR 1483114.
- MR 2046610.
- ^ Hoshi, Yuichiro, Introduction to mono-anabelian geometry (PDF) to appear in Proceedings of the conference “Fundamental Groups in Arithmetic Geometry”, Paris, France 2016. [1] (Semantic Scholar "mono-anabelian geometry" Related Site [2] )
- ^ Mochizuki, Shinichi (2012). "Topics in Absolute Anabelian Geometry I". J. Math. Sci. Univ. Tokyo. 19: 139–242.
- ^ Mochizuki, Shinichi (2013). "Topics in Absolute Anabelian Geometry II". J. Math. Sci. Univ. Tokyo. 20: 171–269.
- ^ Mochizuki, Shinichi (2015). "Topics in Absolute Anabelian Geometry III". J. Math. Sci. Univ. Tokyo. 22: 939–1156.
- ^ Mochizuki, Shinichi (2021). "Inter-universal Teichmuller theory I, II, III, IV". Publ. Res. Inst. Math. Sci. 57: 3–723.
- ^ "Combinatorial Anabelian Geometry and Related Topics, RIMS workshop, July 5-9 2021".
External links
- Foundations and Perspectives of Anabelian Geometry, RIMS workshop, June 28-July 2 2021. https://www.kurims.kyoto-u.ac.jp/~motizuki/RIMS-workshop-homepages-2016-2021/w1/May2020.html
- Combinatorial Anabelian Geometry and Related Topics, RIMS workshop, July 5-9 2021. https://www.kurims.kyoto-u.ac.jp/~motizuki/RIMS-workshop-homepages-2016-2021/w2/June2020.html
- Mochizuki, Shinichi (2012). "Topics in Absolute Anabelian Geometry I". J. Math. Sci. Univ. Tokyo. 19: 139–242.
- Mochizuki, Shinichi (2013). "Topics in Absolute Anabelian Geometry II". J. Math. Sci. Univ. Tokyo. 20: 171–269.
- Mochizuki, Shinichi (2015). "Topics in Absolute Anabelian Geometry III". J. Math. Sci. Univ. Tokyo. 22: 939–1156.
- Mochizuki, Shinichi (2021). "Inter-universal Teichmuller theory I, II, III, IV". Publ. Res. Inst. Math. Sci. 57: 3–723.
- The Grothendieck Conjecture on the Fundamental Groups of Algebraic Curves. http://www4.math.sci.osaka-u.ac.jp/~nakamura/zoo/rhino/NTM300.pdf
- Arithmetic fundamental groups and moduli of curves. http://users.ictp.it/~pub_off/lectures/lns001/Matsumoto/Matsumoto.pdf
- Porowski, Wojtek. "Introduction to anabelian geometry". YouTube.
- Szamuely, Tamás. "Heidelberg Lectures on Fundamental Groups" (PDF). section 5. Archived from the original (PDF) on 2020-04-05. Retrieved 2010-04-26.
- Grothendieck, Alexander. "La Longue Marche à Travers la Théorie de Galois" (PDF). Archived from the original (PDF) on 2022-05-20. Retrieved 2022-01-31.
- MR 1259367