Research – Ivan Fesenko

List of sections:

R Recent
M Epidemic modelling
L Anabelian geometry, IUT theory, and applications
K 2d adelic analysis and geometry, and applications
J Adelic structures on arithmetic and geometric surfaces, and applications
I Higher integration, harmonic analysis and zeta integrals
H Interactions of model theory, arithmetic and algebraic geometry and noncommutative geometry
G Arithmetic noncommutative class field theory and local reciprocity maps
F Infinite ramification theory and pro-p-group theory
E Local field arithmetic, representation theory of algebraic groups
D Ramification theory, finite and infinite Galois extensions, perfect and imperfect residue field
C Higher local fields, their structures, their algebraic K-groups
B Class field theories,  one-dimensional and higher dimensional
A Explicit formulas for generalized Hilbert symbol on local and higher local fields
Textbooks
Surveys
Volumes edited

some files are updated versions of the published versions

       R Recent

• [R14] The effective abc inequality and how it was applied to a new proof of FLT, Zhejiang university, talk October 2023
• [R13] On new interactions between quantum theories and arithmetic geometry, October 2023
• [R12] Core topics in number theory I (algebraic number theory, class field theory)
• [R11] Problems in higher adelic theory, talk April 2023 Beijing
• [R10] Anabelian geometry-IUT-effective abc inequalities-applications, Tsinghua university, talk March 2023
• [R9] Categories, toposes, anabelian geometry, IUT and quantum computing, 110 minutes talk, Crypto-Math CREST workshop, Tokyo, September 2022
  
• [R8] Sh. Mochizuki, I. Fesenko, Yu. Hoshi, A. Minamide, W. Porowski, Explicit estimates in inter-universal Teichmüller theory, Kodai Math. J. 45(2022) 175-236
• [R7] Geometries underlying deep properties of numbers, video of a talk at Institute of Mathematics, Kyiv, Ukraine
• [R6] Higher adelic theory, video of a talk at the Como School, September 2021
• [R5] IUT and modern number theory, talk at the RIMS workshop on IUT Summit, September 2021 
  
• [R4] Class field theory, its three main generalisations, and applications, EMS Surveys 8(2021) 107-133
• [R3] A. Zhigljavsky, J. Noonan, I. Fesenko, K. Kremnitzer et al, A prototype decision support tool for handling the COVID-19 UK epidemic, April 2020
• [R2] A. Zhigljavsky, I. Fesenko, et al, Comparison of different exit scenarios from the lock-down for COVID-19 epidemic in the UK and assessing uncertainty of the predictions, April 2020
• [R1] A. Zhigljavsky, I. Fesenko et al, Generic probabilistic modelling and non-homogeneity issues for the UK epidemic of COVID-19, April 2020
  
  M Epidemic modelling

• [M3] A. Zhigljavsky, J. Noonan, I. Fesenko, K. Kremnitzer et al, A prototype decision support tool for handling the COVID-19 UK epidemic, April 2020
• [M2] A. Zhigljavsky, I. Fesenko, et al, Comparison of different exit scenarios from the lock-down for COVID-19 epidemic in the UK and assessing uncertainty of the predictions, April 2020
• [M1] A. Zhigljavsky, I. Fesenko et al, Generic probabilistic modelling and non-homogeneity issues for the UK epidemic of COVID-19, April 2020
  
  L Anabelian geometry, IUT theory, and applications

• [L5] On new interactions between quantum theories and arithmetic geometry, October 2023
• [L4] Sh. Mochizuki, I. Fesenko, Yu. Hoshi, A. Minamide, W. Porowski, Explicit estimates in inter-universal Teichmüller theory, Kodai Math. J. 45(2022) 175-236
• [L3] Class field theory, its three main generalisations, and applications, EMS Surveys 8(2021) 107-133
• [L2] Fukugen, Inference: International Review of Science 2 no. 3 (2016) 
• [L1] Arithmetic deformation theory via arithmetic fundamental groups and nonarchimedean theta functions, notes on the work of Shinichi Mochizuki, Europ. J. Math. (2015) 1:405–440

• The effective abc inequality and how it was applied to a new proof of FLT, Zhejiang university, talk October 2023
• Anabelian geometry-IUT-effective abc inequalities-applications, Tsinghua university, talk March 2023
• Categories, toposes, anabelian geometry, IUT and quantum computing, Crypto-Math CREST workshop talk, Tokyo, September 2022
• Introducing anabelian geometry, a general talk, 2021
• Geometries underlying deep properties of numbers, video of a talk at Institute of Mathematics, Kyiv, Ukraine 2021
• IUT and modern number theory, talk at RIMS workshop on IUT Summit, September 2021 
• On inter-universal Teichmüller theory of Shinichi Mochizuki, generic 90 minutes talk 
• Reciprocity and IUT, talk at RIMS/S&C workshop on IUT Summit, Kyoto 2016 
• Extended proceedings of Oxford 2015 IUT workshop
• Guides on IUT
  
  K 2d adelic analysis and geometry, and applications

• [K6] Selective integration on higher adeles and the Euler characteristic for surfaces, work in progress
• [K5] Analysis on arithmetic schemes, III, work in progress
• [K4] Class field theory, its three main generalisations, and applications, EMS Surveys 8(2021) 107-133
• [K3] I. Fesenko, G. Ricotta, M. Suzuki, Mean-periodicity and zeta functions, Ann. L’Inst. Fourier, 62 (2012) 1819-188
• [K2] Analysis on arithmetic schemes. II, J. K-theory 5 (2010) 437-557
• [K1] Adelic approach to the zeta function of arithmetic schemes in dimension two, Moscow Math. J. 8 (2008) 273-317

• Problems in higher adelic theory, talk
• Remaining open problems in 2d adelic analysis and geometry  
• Higher adelic theory, video of a 75 minutes talk
• Adelic geometry and analysis on regular models of elliptic curves over global fields and their zeta functions, 90 minutes talk
  
  For related developments see
  
  
• W. Czerniawska, Higher adelic programme, adelic Riemann-Roch theorems and the BSD conjecture, PhD thesis, eprints Nottingham 2018 
• T. Oliver, Zeta integrals on arithmetic surfaces, St. Petersburg Math. J. 27(2016) 
  
  For some of related analytic aspects of zeta functions see 

• M. Suzuki, Two-dimensional adelic analysis and cuspidal automorphic representations of GL(2), 339-361, In Multiple Dirichlet Series, L-functions and automorphic forms,  eds., Progress in Math. 300, Birkhauser 2012
• M. Suzuki, Positivity of certain functions associated with analysis on elliptic surfaces, J. Number Theory 131 (2011) 1770-1796 
• M. Suzuki, On zeta integrals related to Hasse-Weil L-functions of elliptic curves, RIMS, Kokyuroku 1665 (2009) 105-113
• T. Oliver, Hecke characters and the mean-periodicity correspondence for CM elliptic curves, arXiv:1307.6706 
• T. Oliver, Mean-periodicity and automorphicity, J. Math. Soc. Japan 69 (2017) 25-51
  
  J Adelic structures on arithmetic and geometric surfaces, and applications 
  
  
• [J3] Geometric adeles and the Riemann–Roch theorem for 1-cycles on surfaces, Moscow Math. J. 15 (2015) 435-453
• [J2] Analysis on arithmetic schemes. II, J. K-theory 5 (2010) 437-557
• [J1] Adelic approach to the zeta function of arithmetic schemes in dimension two, Moscow Math. J. 8 (2008) 273-317
  
  Higher adelic theory, video of a 75 minutes talk
  
  For some of related arithmetic and geometric aspects see 

• W. Czerniawska, P. Dolce, Adelic geometry on arithmetic surfaces II: completed adeles and idelic Arakelov intersection theory, J. Number Theory 2019, arxiv: 1906:03745 
• P. Dolce, Adelic geometry on arithmetic surfaces I: idelic and adelic interpretation of Deligne pairing, arxiv: 1812.10834 
• P. Dolce, Low dimensional adelic geometry, PhD thesis, eprints Nottingham 2018 
• M. Morrow, Grothendieckʼs trace map for arithmetic surfaces via residues and higher adeles, Algebra & Number Th., 2012, 6-7 (2012)  1503-1536
• M. Morrow, An explicit approach to residues on and dualizing sheaves of arithmetic surfaces, New York J. Math., 16 (2010) 575-627 
• O. Bräunling, Adele residue symbol and Tate’s central extension for multiloop Lie algebras, arXiv:1206.2025  
• O. Bräunling, Two-dimensional ideles with cycle module coefficients, arXiv:1101.0424
  
  I Higher integration, harmonic analysis and zeta integrals
  
  
• [I2] Measure, integration and elements of harmonic analysis on generalized loop spaces, Proceed. St. Petersburg Math. Soc., vol. 12 (2005), 179-199;  AMS Transl. Series 2, vol. 219, 149-164, 2006
• [I1] Analysis on arithmetic schemes. I, Docum. Math.(2003) 261-284
  
  For related measure and integration aspects see 
  
  
• M. Waller, Measure and integration on GL2 over a two-dimensional local field, arXiv:1902.02899, New J. Math. 25 (2019) 396-422
• M. Waller, An approach to harmonic analysis on non-locally compact groups I: level structures over locally compact groups, arXiv:1902.02909
• M. Waller, An approach to harmonic analysis on non-locally compact groups II: an invariant measure on groups of ordered type, arXiv:1902.02913
• M. Morrow, Integration on valuation fields over local fields, Tokyo J. Math., 33 (2010) 235-281
• M. Morrow, Integration on product spaces and GL_n of a valuation field over a local field, Comm. in Number Th. and Physics, 2 (2008)  563-592
• M. Morrow, Fubiniʼs theorem and non-linear changes of variables over a two-dimensional local field, arXiv:0712.2177
  
  H Interactions of model theory, arithmetic and algebraic geometry and noncommutative geometry
  
  
• [H3] Model theory guidance in number theory? –  In Model Theory with Applications to Algebra and Analysis, LMS Lecture Note Series, 349, CUP, 2008, 327-334
• [H2] Several nonstandard remarks, – In AMS/IP Advances in the Mathematical Sciences,  AMS Transl. Series 2, vol. 217 (2006) 37-50
• [H1] Remark 1 sect. 4 and Remark 3 sect. 13 of Analysis on arithmetic schemes. I, Docum. Math., (2003) 261-284
  
  G Arithmetic noncommutative class field theory and local reciprocity maps
  
  
• [G3] On the image of noncommutative reciprocity map, Homology, Homotopy and Applications, 7 (2005) 53-62
• [G2] Noncommutative (nonabelian) local reciprocity maps, In Class Field Theory – Its Centenary and Prospects,  Advanced Studies in Pure Math., vol. 30, 63-78, Math. Soc. Japan, Tokyo 2001
• [G1] Local reciprocity cycles, in Invitation to higher local fields, I. Fesenko, M. Kurihara (eds.) , Geometry and Topology Monographs, Warwick 2000, pp. 293-298.
  
  see also
  
  
• K.I. Ikeda, E. Serbest, Fesenko reciprocity map, St. Petersburg Math. J. 20 (2008) 407-445 
• K.I. Ikeda, E. Serbest, Generalized Fesenko reciprocity map, St. Petersburg Math. J. 20 (2008) 593-624 
• K.I. Ikeda, E. Serbest, Non-abelian local reciprocity law, Manuscr. Math. 132 (2010) 19-49
  
  F Infinite ramification theory and pro-p-group theory
  
  
• [F2] M. du Sautoy, I. Fesenko, Where the wild things are: ramification groups and the Nottingham group, In New horizons in pro-p groups, 287-328, Progr. Math., 184, Birkhauser 2000
• [F1] On just infinite pro-p-groups and arithmetically profinite extensions of local fields, J. Reine Angew. Mathematik 517 (1999) 61-80
  
  E Local field arithmetic, representation theory of algebraic groups
  
  
• [E2] Last section of Adelic approach to the zeta function of arithmetic schemes in dimension two, Moscow Math J 8 (2008) 273-317
• [E1] I. Efrat and I. Fesenko, Fields Galois-equivalent to a local field of positive characteristic, Math. Res. Lett. 6 (1999) 345-356
  
  D Ramification theory, finite and infinite Galois extensions, perfect and imperfect residue field
  
  
• [D4] Ch. 3 of I.B. Fesenko and S.V. Vostokov, Local Fields and Their Extensions,  Second extended edition, AMS 2002, 341 pp.
• [D3] On deeply ramified extensions, Journal of the LMS (2) 57 (1998) 325-335
• [D2] Hasse-Arf property and abelian extensions, Math. Nachr. 174 (1995) 81-87
• [D1] Abelian local p-class field theory, Math. Ann. 301 (1995) 561-586. 
  
  C Higher local fields, their structures, their algebraic K-groups
  
  
• [C5] I. B. Fesenko, S. V. Vostokov, S. H. Yoon, Generalised Kawada-Satake method for Mackey functors in class field theory, Europ. J. Math. 4(2018) 953-987
• [C4] Ch. 9 of I.B. Fesenko and S.V. Vostokov, Local Fields and Their Extensions,  Second extended edition , AMS 2002
• [C3] Sequential topologies and quotients of Milnor K-groups of higher local fields, with appendix by O.T. Izhboldin,  Algebra i Analiz, 13 (2001), issue 3, 198-228; St. Petersburg Math. J. 13 (2002) 485-501
• [C2] Topological Milnor K-groups of higher local fields, in Invitation to higher local fields, I. Fesenko, M. Kurihara (eds.), Geometry and Topology Monographs, Warwick 2000, pp. 61-74
• [C1] On K-groups of a multidimensional local field, Ukraine Mat. J. 41 issue 2 (1989), 266-268; English transl. in Ukrainian Math. J. 41(1989)  237-240
  
  B Class field theories,  one-dimensional and higher dimensional
  
  
• [B17] Core topics in number theory I (algebraic number theory, class field theory)
• [B16] Class field theory, its three main generalisations, and applications, May 2021, EMS Surveys 8(2021) 107-133
• [B15] I. B. Fesenko, S. V. Vostokov, S. H. Yoon, Generalised Kawada-Satake method for Mackey functors in class field theory, Europ. J. Math. 4(2018) 953-987
• [B14] Chapter 3 of Analysis on arithmetic schemes. II, J. K-theory 5 (2010) 437-557
• [B13] Ch. 4, 5 of I.B. Fesenko and S.V. Vostokov, Local Fields and Their Extensions,  Second extended edition , AMS 2002, 341 pp.
• [B12] Explicit higher local class field theory, in Invitation to higher local fields, I. Fesenko, M. Kurihara (eds.), Geometry and Topology Monographs, Warwick 2000, pp. 95-101
• [B11] Higher class field theory without using K-groups, in Invitation to higher local fields, I. Fesenko, M. Kurihara (eds.), Geometry and Topology Monographs, Warwick 2000, pp. 137-142
• [B10] Complete discrete valuation fields. Abelian local class field theories, in Handbook of Algebra (man. ed. M. Hazewinkel), vol. 1, pp. 221-268, Elsevier, Amsterdam 1996
• [B9] On general local reciprocity maps, J. reine angew. Math. 473 (1996) 207-222
• [B8] Abelian extensions of complete discrete valuation fields, Number Theory Paris 1993/94, Cambridge Univ. Press 1996, 47-74
• [B7] Abelian local p-class field theory, Math. Ann. 301 (1995) 561-586
• [B6] Local class field theory: perfect residue field case, Izvest. Russ. Acad. Nauk. Ser. Mat. 57 issue 4(1993) 72-91; English transl. in Russ. Acad. Sc. Izv. Math. 43 (1994) 65-81
• [B5] On norm subgroups of complete discrete valuation fields, Vestn. St. Petersburg Univ. Series I, issue 2 1993, 54-57
• [B4] Class field theory of multidimensional local fields of  characteristic 0, with the residue field of positive characteristic, Algebra i Analiz 3 issue 3 (1991) 165-196; English transl. in St. Petersburg Math. J. 3 (1992) 649-678
• [B3] Multidimensional local class field theory.II, Algebra i Analiz 3 issue 5 (1991) 168-189; English transl. in St. Petersburg Math. J. 3 (1992) 1103-1126
• [B2] Multidimensional local class field theory, Dokl. AN SSSR 318 issue 1 (1991) 47-50; English transl. in  Acad. Scienc. Dokl. Math. 43 (1991) 674-677
• [B1] On class field theory of multidimensional local fields of positive characteristic, Adv. Sov. Math. 4 (1991) 103-127. 
  
  see also
  
  
• K. Syder, Reciprocity laws for the higher tame symbol and the Witt symbol on an algebraic surface, arXiv:1304.6250
• K. Syder, Two-Dimensional local-global class field theory in positive characteristic, arXiv:1403.6747
  
  A Explicit formulas for generalized Hilbert symbol on local and higher local fields
  
  
• [A7] Ch. 7,8 of I.B. Fesenko and S.V. Vostokov, Local Fields and Their Extensions, Second extended edition , AMS 2002
• [A6] The generalized Hilbert symbol in multidimensional local fields, in Rings and Modules, vyp. 2, 1988, 88-92
• [A5] S.V. Vostokov, I.B. Fesenko, A property of the Hilbert pairing,  Matem. Zametki 43(1988), 393-400; English transl. in Mathem. Notes 43 (1988) 226-230
• [A4] Explicit formulas for the generalized Hilbert symbol on Lubin-Tate formal groups – see  Ch. I of 1987 thesis  part i part ii part iii
• [A3] The generalized Hilbert symbol in 2-adic case, Vestnik  St.  Petersburg Univ. 1985 issue 22, 112-114; English transl. in Vestnik St Petersburg Univ. Math. 18 (1985) 88-91
• [A2] The Hilbert symbol on Lubin-Tate formal groups. III, in Rings and matrix groups, 1984, 146-150
• [A1] S.V. Vostokov, I.B. Fesenko, The Hilbert symbol on Lubin-Tate formal groups. II, Zapiski nauch. semin. LOMI 132(1983) 85-96; English transl. in J. Soviet Math. 30 (1985)
  
  Textbooks
  
  
• [T4] Core topics in number theory I (algebraic number theory, class field theory)
• [T3] Invitation to higher local fields, I. Fesenko, M. Kurihara (eds.) Geometry and Topology Monographs vol 3, Warwick 2000, part I, part II
• [T2] I.B. Fesenko and S.V. Vostokov, Local Fields and Their Extensions,  Second extended edition , AMS 2002, 341 pp.
• [T1] I.B. Fesenko and S.V. Vostokov, Local Fields and Their Extensions, A Constructive Approach,  AMS 1993, 284 pp.
  
  Surveys
  
  
• [S7] On new interactions between quantum theories and arithmetic geometry, and beyond
• [S6] Fukugen, Inference: International Review of Science 2 no. 3 (2016) 
• [S5] Arithmetic deformation theory via arithmetic fundamental groups and nonarchimedean theta functions, notes on the work of Shinichi Mochizuki, Europ. J. Math. (2015) 1:405–440
• [S4] Adelic approach to the zeta function of arithmetic schemes in dimension two, Moscow Math. J. 8 (2008), 273-317
• [S3] I. Fesenko,  M. du Sautoy,  Where the wild things are: ramification groups and the Nottingham group, in New horizons in pro-p-groups, Birkhaeuser, 2000, 287-328
• [S2] Abelian extensions of complete discrete valuation fields, Number Theory Paris 1993/94, Cambridge Univ. Press 1996, 47-74
• [S1] Complete discrete valuation fields. Abelian local class field theories, in Handbook of Algebra (man. ed. M. Hazewinkel), vol. 1, pp. 221-268, Elsevier, Amsterdam 1996
  
  Volumes edited
  
  
• [V7] EMS Surveys Volume of 2018 Fuerteventura workshop, 2021, F. Bogomolov, I. Cheltsov, I. Fesenko (eds.) 
• [V6] Documenta Mathematica Volume dedicated to A.S. Merkuriev, 2015, P. Balmer, V. Chernousov, I. Fesenko, E. Friedlander, S. Garibaldi, Z. Reichstein, U. Rehmann (eds.) 
• [V5] Documenta Mathematica Volume dedicated to A.A. Suslin, 2010, 723 pp., I. Fesenko, E. Friedlander, A. Merkuriev, U. Rehmann (eds.) 
• [V4] Documenta Mathematica Volume dedicated to J.H. Coates, 2006, 826 pp., I. Fesenko, S. Lichtenbaum, B. Perrin-Riou, P. Schneider (eds.) 
• [V3] Volumes 11 and 12 of St Petersburg Mathematical Society Proceedings dedicated to S.V. Vostokov, 2005, 416 pp.;  English translation by the AMS, Transl. Series 2 vol. 218, 219, 2006: Volume 1 Volume 2; I. Fesenko, I. Zhukov (eds.)
• [V2] Documenta Mathematica Volume dedicated to K. Kato, 2003, 918 pp., S. Bloch, I. Fesenko, L. Illusie, M. Kurihara, S. Saito, T. Saito, P. Schneider (eds.)
• [V1] Invitation to higher local fields, I. Fesenko, M. Kurihara (eds.), Geometry and Topology Monographs vol 3, Warwick 2000, part I part II