John Lott (mathematician)

John William Lott (born January 12, 1959)[1] is a Professor of Mathematics at the University of California, Berkeley. He is known for contributions to differential geometry.

John W. Lott
John Lott in Oberwolfach 2010.
Born (1959-01-12) January 12, 1959
Alma materUniversity of California, Berkeley
Scientific career
FieldsMathematics
InstitutionsUniversity of California, Berkeley
University of Michigan
Doctoral advisorIsadore Singer

Academic history

Lott received his B.S. from the Massachusetts Institute of Technology in 1978 and M.A. degrees in mathematics and physics from University of California, Berkeley. In 1983, he received a Ph.D. in mathematics under the supervision of Isadore Singer. After postdoctoral positions at Harvard University and the Institut des Hautes Études Scientifiques, he joined the faculty at the University of Michigan. In 2009, he moved to University of California, Berkeley.

Among his awards and honors:

Mathematical contributions

A seminal 1985 article of Dominique Bakry and Michel Émery introduced a generalized Ricci curvature, in which one adds to the usual Ricci curvature the hessian of a function.[2]. In 2003, Lott showed that much of the standard comparison geometry results for the Ricci tensor extend to the Bakry-Émery setting. For instance, if M is a closed and connected Riemannian manifold with positive Bakry-Émery Ricci tensor, then the fundamental group of M must be finite; if instead the Bakry-Émery Ricci tensor is negative, then the isometry group of the Riemannian manifold must be finite. The comparison geometry of the Bakry-Émery Ricci tensor was taken further in a influential article of Guofang Wei and William Wylie.[3] Additionally, Lott showed that if a Riemannian manifold with smooth density arises as a collapsed limit of Riemannian manifolds with an uniform upper bound on diameter and sectional curvature and a uniform lower bound on Ricci curvature, then the lower bound on Ricci curvature is preserved in the limit as a lower bound on Bakry-Émery's Ricci curvature. In this sense, the Bakry-Émery Ricci tensor is shown to be natural in the context of Riemannian convergence theory.

In 2002 and 2003, Grigori Perelman posted two papers to the arXiv which claimed to provide a proof for William Thurston's geometrization conjecture, using Richard Hamilton's theory of Ricci flow.[4][5] Perelman's papers attracted immediate attention for their bold claims and the fact that some of their results were quickly verified. However, due to Perelman's abbreviated style of presentation of highly technical material, many mathematicians were unable to understand much of his work, especially in his second paper. Beginning in 2003, Lott and Bruce Kleiner posted a series of annotations of Perelman's work to their websites, which was finalized in a 2008 publication.[6] Their article was most recently updated in 2013, to fix an incorrect statement of Hamilton's compactness theorem. In 2015, Kleiner and Lott were awarded the Award for Scientific Reviewing from the National Academy of Sciences of the United States for their work. Other well-known expositions of Perelman's work are due to Huai-Dong Cao and Xi-Ping Zhu, and to John Morgan and Gang Tian.[7][8]

In 2005, Max-K. von Renesse and Karl-Theodor Sturm showed that the a lower bound of the Ricci curvature on a Riemannian manifold could be characterized by optimal transportation, in particular by the convexity of a certain "entropy" functional along geodesics of the associated Wasserstein metric space.[9] In 2009, Lott and Cédric Villani capitalized upon this equivalence to define a notion of "lower bound for Ricci curvature" for a general class of metric spaces equipped with Borel measures. Similar work was done at the same time by Sturm, with the accumulated results typically referred to as "Lott-Sturm-Villani theory".[10][11] The papers of Lott-Villani and Sturm have initiated a very large amount of research in the mathematical literature, much of which is centered around extending classical work on Riemannian geometry to the setting of metric measure spaces.[12][13][14] An essentially analogous program for sectional curvature bounds (from either below or above) was initiated in the 1990s by a highly influential article of Yuri Burago, Mikhail Gromov, and Grigori Perelman, following foundations laid in the 1950s by Aleksandr Aleksandrov.[15]

Major publications

  • Lott, John. Some geometric properties of the Bakry-Émery-Ricci tensor. Comment. Math. Helv. 78 (2003), no. 4, 865–883.
  • Kleiner, Bruce; Lott, John. Notes on Perelman's papers. Geom. Topol. 12 (2008), no. 5, 2587–2855.
  • Lott, John; Villani, Cédric. Ricci curvature for metric-measure spaces via optimal transport. Ann. of Math. (2) 169 (2009), no. 3, 903–991.
gollark: β
gollark: +>eval 4
gollark: This is EXTREMELY.
gollark: +>eval 5
gollark: +>perms

References

  1. CV
  2. Bakry, D.; Émery, Michel. Diffusions hypercontractives. Séminaire de probabilités, XIX, 1983/84, 177–206, Lecture Notes in Math., 1123, Springer, Berlin, 1985.
  3. Wei, Guofang; Wylie, Will. Comparison geometry for the Bakry-Emery Ricci tensor. J. Differential Geom. 83 (2009), no. 2, 377–405.
  4. Perelman, Grisha. The entropy formula for the Ricci flow and its geometric applications. arXiv:math/0211159
  5. Perelman, Grisha. Ricci flow with surgery on three-manifolds. arXiv:math/0303109
  6. Kleiner, Bruce; Lott, John Notes on Perelman's papers. Geom. Topol. 12 (2008), no. 5, 2587–2855.
  7. Cao, Huai-Dong; Zhu, Xi-Ping. A complete proof of the Poincaré and geometrization conjectures—application of the Hamilton-Perelman theory of the Ricci flow. Asian J. Math. 10 (2006), no. 2, 165–492.
  8. Morgan, John; Tian, Gang. Ricci flow and the Poincaré conjecture. Clay Mathematics Monographs, 3. American Mathematical Society, Providence, RI; Clay Mathematics Institute, Cambridge, MA, 2007. xlii+521 pp. ISBN 978-0-8218-4328-4
  9. von Renesse, Max-K.; Sturm, Karl-Theodor. Transport inequalities, gradient estimates, entropy, and Ricci curvature. Comm. Pure Appl. Math. 58 (2005), no. 7, 923–940.
  10. Sturm, Karl-Theodor On the geometry of metric measure spaces. I. Acta Math. 196 (2006), no. 1, 65–131.
  11. Sturm, Karl-Theodor On the geometry of metric measure spaces. II. Acta Math. 196 (2006), no. 1, 133–177.
  12. Ambrosio, Luigi; Gigli, Nicola; Savaré, Giuseppe. Metric measure spaces with Riemannian Ricci curvature bounded from below. Duke Math. J. 163 (2014), no. 7, 1405–1490.
  13. Ambrosio, Luigi; Gigli, Nicola; Savaré, Giuseppe. Calculus and heat flow in metric measure spaces and applications to spaces with Ricci bounds from below. Invent. Math. 195 (2014), no. 2, 289–391.
  14. Erbar, Matthias; Kuwada, Kazumasa; Sturm, Karl-Theodor. On the equivalence of the entropic curvature-dimension condition and Bochner's inequality on metric measure spaces. Invent. Math. 201 (2015), no. 3, 993–1071.
  15. Burago, Yu.; Gromov, M.; Perelʹman, G. A.D. Aleksandrov spaces with curvatures bounded below. Uspekhi Mat. Nauk 47 (1992), no. 2(284), 3–51, 222. English translation in Russian Math. Surveys 47 (1992), no. 2, 1–58.
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