Karen Vogtmann

Karen Vogtmann FRS (born July 13, 1949 in Pittsburg, California[1]) is an American mathematician working primarily in the area of geometric group theory. She is known for having introduced, in a 1986 paper with Marc Culler,[2] an object now known as the Culler–Vogtmann Outer space. The Outer space is a free group analog of the Teichmüller space of a Riemann surface and is particularly useful in the study of the group of outer automorphisms of the free group on n generators, Out(Fn). Vogtmann is a professor of mathematics at Cornell University and the University of Warwick.

Karen Vogtmann

Born (1949-07-13) July 13, 1949
NationalityAmerican
Alma materPh.D., 1977 University of California, Berkeley
Known forCuller–Vogtmann Outer space
Awards
Scientific career
Fields
Institutions
ThesisHomology stability for 0n,n (1977)
Doctoral advisorJohn Bason Wagoner
Doctoral students

Biographical data

Vogtmann was inspired to pursue mathematics by a National Science Foundation summer program for high school students at the University of California, Berkeley.[3]

She received a B.A. from the University of California, Berkeley in 1971. Vogtmann then obtained a PhD in mathematics, also from the University of California, Berkeley in 1977.[4] Her PhD advisor was John Wagoner and her doctoral thesis was on algebraic K-theory.[3]

She then held positions at University of Michigan, Brandeis University and Columbia University.[5] Vogtmann has been a faculty member at Cornell University since 1984, and she became a full professor at Cornell in 1994.[5] In September 2013, she also joined the University of Warwick. She is married to the mathematician John Smillie. The couple moved in 2013 to England and settled in Kenilworth.[6] She is currently a professor of mathematics at Warwick, and a Goldwin Smith Professor of Mathematics Emeritus at Cornell.[5]

Vogtmann has been the vice-president of the American Mathematical Society (2003–2006).[4][7] She has been elected to serve as a member of the board of trustees of the American Mathematical Society for the period February 2008 – January 2018.[8][9]

Vogtmann is a former editorial board member (2006–2016) of the journal Algebraic and Geometric Topology and a former associate editor of Bulletin of the American Mathematical Society.[5] She is currently an associate editor of the Journal of the American Mathematical Society,[10] an editorial board member Geometry & Topology Monographs book series,[11] and a consulting editor for the Proceedings of the Edinburgh Mathematical Society.[12]

She is also a member of the ArXiv advisory board.[13]

Since 1986 Vogtmann has been a co-organizer of the annual conference called the Cornell Topology Festival[14] that usually takes places at Cornell University each May.

Awards, honors and other recognition

Vogtmann gave an invited lecture at the International Congress of Mathematicians in Madrid, Spain, in August 2006.[15][16]

She gave the 2007 annual AWM Noether Lecture titled "Automorphisms of Free Groups, Outer Space and Beyond" at the annual meeting of American Mathematical Society in New Orleans in January 2007.[3][17] Vogtmann was selected to deliver the Noether Lecture for "her fundamental contributions to geometric group theory; in particular, to the study of the automorphism group of a free group".[18]

On June 21–25, 2010 a 'VOGTMANNFEST' Geometric Group Theory conference in honor of Vogtmann's birthday was held in Luminy, France.[19]

In 2012 she became a fellow of the American Mathematical Society.[20] She became a member of the Academia Europaea in 2020.[21] She was elected to the American Academy of Arts and Sciences in 2023.[22]

Vogtmann received the Royal Society Wolfson Research Merit Award in 2014.[23] She also received the Humboldt Research Award from the Humboldt Foundation in 2014.[24][25] She was named MSRI Clay Senior Scholar in 2016 and Simons Professor for 2016-2017.[26][27]

Vogtmann gave a plenary talk at the 2016 European Congress of Mathematics in Berlin.[28][29]

In 2018 she won the Pólya Prize of the London Mathematical Society "for her profound and pioneering work in geometric group theory, particularly the study of automorphism groups of free groups".[30]

In May 2021 she was elected a Fellow of the Royal Society.[31]

In 2022 she was elected to the National Academy of Sciences (NAS).[32]

Mathematical contributions

Vogtmann's early work concerned homological properties of orthogonal groups associated to quadratic forms over various fields.[33][34]

Vogtmann's most important contribution came in a 1986 paper with Marc Culler called "Moduli of graphs and automorphisms of free groups".[2] The paper introduced an object that came to be known as Culler–Vogtmann Outer space. The Outer space Xn, associated to a free group Fn, is a free group analog[35] of the Teichmüller space of a Riemann surface. Instead of marked conformal structures (or, in an equivalent model, hyperbolic structures) on a surface, points of the Outer space are represented by volume-one marked metric graphs. A marked metric graph consists of a homotopy equivalence between a wedge of n circles and a finite connected graph Γ without degree-one and degree-two vertices, where Γ is equipped with a volume-one metric structure, that is, assignment of positive real lengths to edges of Γ so that the sum of the lengths of all edges is equal to one. Points of Xn can also be thought of as free and discrete minimal isometric actions Fn on real trees where the quotient graph has volume one.

By construction the Outer space Xn is a finite-dimensional simplicial complex equipped with a natural action of Out(Fn) which is properly discontinuous and has finite simplex stabilizers. The main result of Culler–Vogtmann 1986 paper,[2] obtained via Morse-theoretic methods, was that the Outer space Xn is contractible. Thus the quotient space Xn /Out(Fn) is "almost" a classifying space for Out(Fn) and it can be thought of as a classifying space over Q. Moreover, Out(Fn) is known to be virtually torsion-free, so for any torsion-free subgroup H of Out(Fn) the action of H on Xn is discrete and free, so that Xn/H is a classifying space for H. For these reasons the Outer space is a particularly useful object in obtaining homological and cohomological information about Out(Fn). In particular, Culler and Vogtmann proved[2] that Out(Fn) has virtual cohomological dimension 2n  3.

In their 1986 paper Culler and Vogtmann do not assign Xn a specific name. According to Vogtmann,[36] the term Outer space for the complex Xn was later coined by Peter Shalen. In subsequent years the Outer space became a central object in the study of Out(Fn). In particular, the Outer space has a natural compactification, similar to Thurston's compactification of the Teichmüller space, and studying the action of Out(Fn) on this compactification yields interesting information about dynamical properties of automorphisms of free groups.[37][38][39][40]

Much of Vogtmann's subsequent work concerned the study of the Outer space Xn, particularly its homotopy, homological and cohomological properties, and related questions for Out(Fn). For example, Hatcher and Vogtmann[41][42] obtained a number of homological stability results for Out(Fn) and Aut(Fn).

In her papers with Conant,[43][44][45] Vogtmann explored the connection found by Maxim Kontsevich between the cohomology of certain infinite-dimensional Lie algebras and the homology of Out(Fn).

A 2001 paper of Vogtmann, joint with Louis Billera and Susan P. Holmes, used the ideas of geometric group theory and CAT(0) geometry to study the space of phylogenetic trees, that is trees showing possible evolutionary relationships between different species.[46] Identifying precise evolutionary trees is an important basic problem in mathematical biology and one also needs to have good quantitative tools for estimating how accurate a particular evolutionary tree is. The paper of Billera, Vogtmann and Holmes produced a method for quantifying the difference between two evolutionary trees, effectively determining the distance between them.[47] The fact that the space of phylogenetic trees has "non-positively curved geometry", particularly the uniqueness of shortest paths or geodesics in CAT(0) spaces, allows using these results for practical statistical computations of estimating the confidence level of how accurate particular evolutionary tree is. A free software package implementing these algorithms has been developed and is actively used by biologists.[47]

Selected works

See also

References

  1. Biographies of Candidates 2002. Notices of the American Mathematical Society. September 2002, Volume 49, Issue 8, pp. 970–981
  2. Culler, Marc; Vogtmann, Karen (1986), "Moduli of graphs and automorphisms of free groups" (PDF), Inventiones Mathematicae, 84 (1): 91–119, Bibcode:1986InMat..84...91C, doi:10.1007/BF01388734, S2CID 122869546.
  3. Karen Vogtmann Archived 2016-10-22 at the Wayback Machine, 2007 Noether Lecture, Profiles of Women in Mathematics. The Emmy Noether Lectures. Association for Women in Mathematics. Accessed November 28, 2008
  4. Biographies of Candidates 2007. Notices of the American Mathematical Society. September 2007, Volume 54, Issue 8, pp. 1043–1057
  5. CURRICULUM VITAE - Karen Vogtmann, University of Warwick. Accessed September 14, 2017
  6. "Obituary | Anna K. Smillie (1929–2020)". Cremation Society of the Carolinas.
  7. 2002 Election results. Notices of the American Mathematical Society. February 2003, Volume 50 Issue 2, p. 281
  8. 2007 Election Results. Notices of the American Mathematical Society. February 2008, Volume 55, Issue 2, p. 301
  9. 2012 Election Results, Notices of the American Mathematical Society, February 2013, Volume 60, Issue 2, p. 256
  10. editorial board, Journal of the American Mathematical Society. Accessed September 14, 2017.
  11. editorial board, Geometry & Topology Monographs. Accessed September 14, 2017
  12. editorial board, Proceedings of the Edinburgh Mathematical Society. Accessed September 14, 2017.
  13. ArXiv Advisory Board. ArXiv. Accessed November 27, 2008
  14. Cornell Topology Festival, grant summary. Cornell University. Accessed November 28, 2008
  15. ICM 2006 – Invited Lectures. Abstracts Archived March 3, 2016, at the Wayback Machine, International Congress of Mathematicians, 2006.
  16. Karen Vogtmann, The cohomology of automorphism groups of free groups. International Congress of Mathematicians. Vol. II, 1101–1117, Invited lectures. Proceedings of the congress held in Madrid, August 22–30, 2006. Edited by Marta Sanz-Solé, Javier Soria, Juan Luis Varona and Joan Verdera. European Mathematical Society (EMS), Zürich, 2006. ISBN 978-3-03719-022-7
  17. Invited Addresses, Sessions, and Other Activities. AMS 2007 Annual Meeting. American Mathematical Society. Accessed November 28, 2008
  18. Karen Vogtmann named 2007 Noether Lecturer. Archived 2008-05-16 at the Wayback Machine Association for Women in Mathematics press release. May 2, 2006. Accessed November 29, 2008
  19. VOGTMANNFEST, conference info. Department of Mathematics, University of Utah. Accessed July 13, 2010
  20. List of Fellows of the American Mathematical Society, retrieved 2013-08-29.
  21. List of members, Academia Europaea, retrieved October 2, 2020
  22. New members, American Academy of Arts and Sciences, 2023, retrieved April 21, 2023
  23. Royal Society announces new round of esteemed Wolfson Research Merit Awards, The Royal Society press release, 09 May 2014. Accessed 14 September 2017.
  24. Awards: since March 2013 Archived 2017-09-14 at the Wayback Machine, Alexander von Humboldt Foundation. Accessed September 14, 2017
  25. Karen Vogtmann receives Humboldt Research Award, Math Matters. Department of Mathematics, Cornell University, December 2014; p. 2
  26. Karen Vogtmann: Recent Senior Scholars, Clay Mathematics Institute. Accessed September 14, 2017
  27. MSRI. "Mathematical Sciences Research Institute". www.msri.org. Retrieved June 7, 2021.
  28. 7ECM Plenary Talks, 7th European Congress of Mathematics, July 18–22, 2016. The quadrennial Congress of the European Mathematical Society. Accessed September 14, 2017
  29. Editorial: 7th European Congress of Mathematics, Newsletter of the European Mathematical Society, June 2015, issue 96, p. 3
  30. "Prizes of the London Mathematical Society" (PDF), Mathematics People, Notices of the American Mathematical Society, 65 (9): 1122, October 2018
  31. "Royal Society elects outstanding new Fellows and Foreign Members". The Royal Society. May 6, 2021. Retrieved May 21, 2021.
  32. "2022 NAS Election". www.nasonline.org. Retrieved May 22, 2022.
  33. Karen Vogtmann, Spherical posets and homology stability for . Topology, vol. 20 (1981), no. 2, pp. 119–132.
  34. Karen Vogtmann, A Stiefel complex for the orthogonal group of a field. Commentarii Mathematici Helvetici, vol. 57 (1982), no. 1, pp. 11–21
  35. Benson Farb. Problems on Mapping Class Groups and Related Topics. American Mathematical Society, 2006. ISBN 978-0-8218-3838-9; p. 335
  36. Karen Vogtmann, Automorphisms of free groups and Outer space. Geometriae Dedicata, vol. 94 (2002), pp. 1–31; Quote from p. 3: "Peter Shalen later invented the name Outer space for Xn".
  37. M. Bestvina, M. Feighn, M. Handel, Laminations, trees, and irreducible automorphisms of free groups. Geometric and Functional Analysis, vol. 7 (1997), no. 2, 215–244
  38. Gilbert Levitt and Martin Lustig, Irreducible automorphisms of Fn have north-south dynamics on compactified Outer space. Journal of the Institute of Mathematics of Jussieu, vol. 2 (2003), no. 1, 59–72
  39. Gilbert Levitt, and Martin Lustig, Automorphisms of free groups have asymptotically periodic dynamics. Crelle's Journal, vol. 619 (2008), pp. 1–36
  40. Vincent Guirardel, Dynamics of Out(Fn) on the boundary of Outer space. Annales Scientifiques de l'École Normale Supérieure (4), vol. 33 (2000), no. 4, 433–465.
  41. Allen Hatcher, and Karen Vogtmann. Cerf theory for graphs. Journal of the London Mathematical Society (2), vol. 58 (1998), no. 3, pp. 633–655.
  42. A. Hatcher, and K. Vogtmann, Homology stability for outer automorphism groups of free groups. Archived 2016-03-03 at the Wayback Machine Algebraic and Geometric Topology, vol. 4 (2004), pp. 1253–1272
  43. James Conant, and Karen Vogtmann. On a theorem of Kontsevich. Algebraic and Geometric Topology, vol. 3 (2003), pp. 1167–1224
  44. James Conant, and Karen Vogtmann, Infinitesimal operations on complexes of graphs. Mathematische Annalen, vol. 327 (2003), no. 3, pp. 545–573.
  45. James Conant, and Karen Vogtmann, Morita classes in the homology of automorphism groups of free groups. Geometry & Topology, vol. 8 (2004), pp. 1471–1499
  46. Billera, Louis J.; Holmes, Susan P.; Vogtmann, Karen (2001). "A Grove of Evolutionary Trees". Advances in Applied Mathematics. 27 (4): 733–767. CiteSeerX 10.1.1.29.3424. doi:10.1006/aama.2001.0759. MR 1867931.
  47. Julie Rehmeyer. A Grove of Evolutionary Trees. Science News. May 10, 2007. Accessed November 28, 2008
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