Rostislav Grigorchuk

Rostislav Ivanovich Grigorchuk (Russian: Ростисла́в Ива́нович Григорчу́к; b. February 23, 1953) is a Soviet and Russian mathematician working in the area of group theory. He holds the rank of Distinguished Professor in the Mathematics Department of Texas A&M University. Grigorchuk is particularly well known for having constructed, in a 1984 paper,[1] the first example of a finitely generated group of intermediate growth, thus answering an important problem posed by John Milnor in 1968. This group is now known as the Grigorchuk group[2][3][4][5][6] and it is one of the important objects studied in geometric group theory, particularly in the study of branch groups, automata groups and iterated monodromy groups.

Rostislav Ivanovich Grigorchuk
Rostislav Grigorchuk (left)
Born (1953-02-23) February 23, 1953
Mukhavets, Ternopil Oblast, Ukrainian SSR (present day Ukraine)
NationalityRussia
Alma materMoscow State University
Known forresearch in geometric group theory, discovering the Grigorchuk group
AwardsLeroy P. Steele Prize (2015)
Scientific career
FieldsMathematics
InstitutionsTexas A&M University

Biographical data

Grigorchuk was born on February 23, 1953 in Ternopil Oblast, now Ukraine (in 1953 part of the USSR).[7] He received his undergraduate degree in 1975 from Moscow State University. He obtained a PhD (Candidate of Science) in Mathematics in 1978, also from Moscow State University, where his thesis advisor was Anatoly M. Stepin. Grigorchuk received a habilitation (Doctor of Science) degree in Mathematics in 1985 at the Steklov Institute of Mathematics in Moscow.[7] During the 1980s and 1990s, Rostislav Grigorchuk held positions at the Moscow State University of Transportation, and subsequently at the Steklov Institute of Mathematics and Moscow State University.[7] In 2002 Grigorchuk joined the faculty of Texas A&M University as a Professor of Mathematics, and he was promoted to the rank of Distinguished Professor in 2008.[8]

Rostislav Grigorchuk gave an invited address at the 1990 International Congress of Mathematicians in Kyoto[9] an AMS Invited Address at the March 2004 meeting of the American Mathematical Society in Athens, Ohio[10] and a plenary talk at the 2004 Winter Meeting of the Canadian Mathematical Society.[11]

Grigorchuk is the Editor-in-Chief of the journal "Groups, Geometry and Dynamics",[12] published by the European Mathematical Society, and a member of the editorial boards of the journals "International Journal of Algebra and Computation",[13] "Journal of Modern Dynamics",[14] "Geometriae Dedicata",[15] "Algebra and Discrete Mathematics",[16] "Bulletin of Chernivtsi University" and "Matematychni Studii".

Mathematical contributions

Grigorchuk is most well known for having constructed the first example of a finitely generated group of intermediate growth which now bears his name and is called the Grigorchuk group (sometimes it is also called the first Grigorchuk group since Grigorchuk constructed several other groups that are also commonly studied). This group has growth that is faster than polynomial but slower than exponential. Grigorchuk constructed this group in a 1980 paper[17] and proved that it has intermediate growth in a 1984 article.[1] This result answered a long-standing open problem posed by John Milnor in 1968 about the existence of finitely generated groups of intermediate growth. Grigorchuk's group has a number of other remarkable mathematical properties. It is a finitely generated infinite residually finite 2-group (that is, every element of the group has a finite order which is a power of 2). It is also the first example of a finitely generated group that is amenable but not elementary amenable, thus providing an answer to another long-standing problem, posed by Mahlon Day in 1957.[18] Also Grigorchuk's group is "just infinite": that is, it is infinite but every proper quotient of this group is finite.[2]

Grigorchuk's group is a central object in the study of the so-called branch groups and automata groups. These are finitely generated groups of automorphisms of rooted trees that are given by particularly nice recursive descriptions and that have remarkable self-similar properties. The study of branch, automata and self-similar groups has been particularly active in the 1990s and 2000s and a number of unexpected connections with other areas of mathematics have been discovered there, including dynamical systems, differential geometry, Galois theory, ergodic theory, random walks, fractals, Hecke algebras, bounded cohomology, functional analysis, and others. In particular, many of these self-similar groups arise as iterated monodromy groups of complex polynomials. Important connections have been discovered between the algebraic structure of self-similar groups and the dynamical properties of the polynomials in question, including encoding their Julia sets.[19]

Much of Grigorchuk's work in the 1990s and 2000s has been on developing the theory of branch, automata and self-similar groups and on exploring these connections. For example, Grigorchuk, with co-authors, obtained a counter-example to the conjecture of Michael Atiyah about L2-betti numbers of closed manifolds.[20][21]

Grigorchuk is also known for his contributions to the general theory of random walks on groups and the theory of amenable groups, particularly for obtaining in 1980[22] what is commonly known (see for example [23][24][25]) as Grigorchuk's co-growth criterion of amenability for finitely generated groups.

Awards and honors

In June 2003 an international group theory conference in honor of Grigorchuk's 50th birthday was held in Gaeta, Italy.[26] Special anniversary issues of the "International Journal of Algebra and Computation" and of the journal "Algebra and Discrete Mathematics" were dedicated to Grigorchuk's 50th birthday.[7][27]

In 2012 he became a fellow of the American Mathematical Society.[28] In 2015 Rostislav Grigorchuk was awarded the AMS Leroy P. Steele Prize for Seminal Contribution to Research.[29]

See also

References

  1. R. I. Grigorchuk, Degrees of growth of finitely generated groups and the theory of invariant means. Izvestiya Akademii Nauk SSSR. Seriya Matematicheskaya. vol. 48 (1984), no. 5, pp. 939-985
  2. Pierre de la Harpe. Topics in geometric group theory. Chicago Lectures in Mathematics. University of Chicago Press, Chicago. ISBN 0-226-31719-6
  3. Laurent Bartholdi. The growth of Grigorchuk's torsion group. International Mathematics Research Notices, 1998, no. 20, pp. 1049-1054
  4. Tullio Ceccherini-Silberstein, Antonio Machì, and Fabio Scarabotti. The Grigorchuk group of intermediate growth. Rendiconti del Circolo Matematico di Palermo (2), vol. 50 (2001), no. 1, pp. 67-102
  5. Yu. G. Leonov. On a lower bound for the growth function of the Grigorchuk group. (in Russian). Matematicheskie Zametki, vol. 67 (2000), no. 3, pp. 475-477; translation in: Mathematical Notes, vol. 67 (2000), no. 3-4, pp. 403-405
  6. Roman Muchnik, and Igor Pak. Percolation on Grigorchuk groups. Communications in Algebra, vol. 29 (2001), no. 2, pp. 661-671.
  7. Editorial Statement, Algebra and Discrete Mathematics, (2003), no. 4
  8. 2008 Personal News, Department of Mathematics, Texas A&M University. Accessed January 15, 2010.
  9. R. I. Grigorchuk. On growth in group theory. Proceedings of the International Congress of Mathematicians, Vol. I, II (Kyoto, 1990), pp. 325-338, Math. Soc. Japan, Tokyo, 1991
  10. Spring Central Section Meeting, Athens, OH, March 26-27, 2004. American Mathematical Society. Accessed January 15, 2010.
  11. 2004 Winter Meeting, Canadian Mathematical Society. Accessed January 15, 2010.
  12. Groups, Geometry and Dynamics
  13. Editorial Board, International Journal of Algebra and Computation
  14. Editorial Board, Journal of Modern Dynamics
  15. Editorial Board, Geometriae Dedicata
  16. Editorial Board, Algebra and Discrete Mathematics Archived 2008-11-21 at the Wayback Machine
  17. R. I. Grigorchuk. On Burnside's problem on periodic groups. (Russian) Funktsionalnyi Analiz i ego Prilozheniya, vol. 14 (1980), no. 1, pp. 53-54
  18. Mahlon M. Day. Amenable semigroups. Illinois Journal of Mathematics, vol. 1 (1957), pp. 509-544.
  19. Volodymyr Nekrashevych. Self-similar groups. Mathematical Surveys and Monographs, 117. American Mathematical Society, Providence, RI, 2005. ISBN 0-8218-3831-8
  20. R. I. Grigorchuk, and A. Zuk. The lamplighter group as a group generated by a 2-state automaton, and its spectrum. Geometriae Dedicata, vol. 87 (2001), no. 1-3, pp. 209--244.
  21. R. I. Grigorchuk, P. Linnell, T. Schick, and A. Zuk. On a question of Atiyah. Comptes Rendus de l'Académie des Sciences, Série I. vol. 331 (2000), no. 9, pp. 663-668.
  22. R. I. Grigorchuk. Symmetrical random walks on discrete groups. Multicomponent random systems, pp. 285-325, Adv. Probab. Related Topics, 6, Marcel Dekker, New York, 1980; ISBN 0-8247-6831-0
  23. R. Ortner, and W. Woess. Non-backtracking random walks and cogrowth of graphs. Canadian Journal of Mathematics, vol. 59 (2007), no. 4, pp. 828-844
  24. Sam Northshield. Quasi-regular graphs, cogrowth, and amenability. Dynamical systems and differential equations (Wilmington, NC, 2002). Discrete and Continuous Dynamical Systems, Series A. 2003, suppl., pp. 678-687.
  25. Richard Sharp. Critical exponents for groups of isometries. Geometriae Dedicata, vol. 125 (2007), pp. 63-74
  26. International Conference on GROUP THEORY: combinatorial, geometric, and dynamical aspects of infinite groups. Archived 2010-12-12 at the Wayback Machine
  27. Preface, International Journal of Algebra and Computation, vol. 15 (2005), no. 5-6, pp. v-vi
  28. List of Fellows of the American Mathematical Society, retrieved 2013-01-19.
  29. AMS 2015 Leroy P. Steele Prize
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