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Tian Gang

November 23, 2023

In this Chinese name, the family name is Tian.

Tian Gang (Chinese: 田刚; born November 24, 1958)[1] is a Chinese mathematician. He is a professor of mathematics at Peking University and Higgins Professor Emeritus at Princeton University. He is known for contributions to the mathematical fields of Kähler geometry, Gromov-Witten theory, and geometric analysis.

Tian Gang
Tian at Oberwolfach in 2005
Born (1958-11-24) 24 November 1958 (age 64)
Nanjing, Jiangsu, China
NationalityChinese
Alma materHarvard University
Peking University
Nanjing University
Known forYau-Tian-Donaldson conjecture
K-stability
K-stability of Fano varieties
AwardsVeblen Prize (1996)
Alan T. Waterman Award (1994)
Scientific career
FieldsMathematics
InstitutionsPrinceton University
Peking University
ThesisKähler Metrics on Algebraic Manifolds (1988)
Doctoral advisorShing-Tung Yau
Doctoral studentsNataša Šešum
Wei Dongyi
Chinese name
Traditional Chinese田剛
Simplified Chinese田刚
Transcriptions
Standard Mandarin
Hanyu PinyinTián Gāng

As of 2020, he is the Vice Chairman of the China Democratic League and the President of the Chinese Mathematical Society. From 2017 to 2019 he served as the Vice President of Peking University.

Biography edit

Tian was born in Nanjing, Jiangsu, China. He qualified in the second college entrance exam after Cultural Revolution in 1978. He graduated from Nanjing University in 1982, and received a master's degree from Peking University in 1984. In 1988, he received a Ph.D. in mathematics from Harvard University, under the supervision of Shing-Tung Yau.

In 1998, he was appointed as a Cheung Kong Scholar professor at Peking University. Later his appointment was changed to Cheung Kong Scholar chair professorship. He was a professor of mathematics at the Massachusetts Institute of Technology from 1995 to 2006 (holding the chair of Simons Professor of Mathematics from 1996). His employment at Princeton started from 2003, and was later appointed the Higgins Professor of Mathematics. Starting 2005, he has been the director of the Beijing International Center for Mathematical Research (BICMR);[2] from 2013 to 2017 he was the Dean of School of Mathematical Sciences at Peking University.[3] He and John Milnor are Senior Scholars of the Clay Mathematics Institute (CMI). In 2011, Tian became director of the Sino-French Research Program in Mathematics at the Centre national de la recherche scientifique (CNRS) in Paris. In 2010, he became scientific consultant for the International Center for Theoretical Physics in Trieste, Italy.[4]

Tian has served on many committees, including for the Abel Prize and the Leroy P. Steele Prize.[5] He is a member of the editorial boards of many journals, including Advances in Mathematics and the Journal of Geometric Analysis. In the past he has been on the editorial boards of Annals of Mathematics and the Journal of the American Mathematical Society.

Among his awards and honors:

Since at least 2013 he has been heavily involved in Chinese politics, serving as the Vice Chairman of the China Democratic League, the second most populous political party in China.

Mathematical contributions edit

The Kähler-Einstein problem edit

Tian is well-known for his contributions to Kähler geometry, and in particular to the study of Kähler-Einstein metrics. Shing-Tung Yau, in his renowned resolution of the Calabi conjecture, had settled the case of closed Kähler manifolds with nonpositive first Chern class. His work in applying the method of continuity showed that C0 control of the Kähler potentials would suffice to prove existence of Kähler-Einstein metrics on closed Kähler manifolds with positive first Chern class, also known as "Fano manifolds." Tian and Yau extended Yau's analysis of the Calabi conjecture to noncompact settings, where they obtained partial results.[TY90] They also extended their work to allow orbifold singularities.[TY91]

Tian introduced the "α-invariant," which is essentially the optimal constant in the Moser-Trudinger inequality when applied to Kähler potentials with a supremal value of 0. He showed that if the α-invariant is sufficiently large (i.e. if a sufficiently strong Moser-Trudinger inequality holds), then C0 control in Yau's method of continuity could be achieved.[T87b] This was applied to demonstrate new examples of Kähler-Einstein surfaces. The case of Kähler surfaces was revisited by Tian in 1990, giving a complete resolution of the Kähler-Einstein problem in that context.[T90b] The main technique was to study the possible geometric degenerations of a sequence of Kähler-Einstein metrics, as detectable by the Gromov–Hausdorff convergence. Tian adapted many of the technical innovations of Karen Uhlenbeck, as developed for Yang-Mills connections, to the setting of Kähler metrics. Some similar and influential work in the Riemannian setting was done in 1989 and 1990 by Michael Anderson, Shigetoshi Bando, Atsushi Kasue, and Hiraku Nakajima.[6][7][8]

Tian's most renowned contribution to the Kähler-Einstein problem came in 1997. Yau had conjectured in the 1980s, based partly in analogy to the Donaldson-Uhlenbeck-Yau theorem, that existence of a Kähler-Einstein metric should correspond to stability of the underlying Kähler manifold in a certain sense of geometric invariant theory. It was generally understood, especially following work of Akito Futaki,[9] that the existence of holomorphic vector fields should act as an obstruction to the existence of Kähler-Einstein metrics. Tian and Wei Yue Ding established that this obstruction is not sufficient within the class of Kähler orbifolds.[DT92] Tian, in his 1997 article, gave concrete examples of Kähler manifolds (rather than orbifolds) which had no holomorphic vector fields and also no Kähler-Einstein metrics, showing that the desired criterion lies deeper.[T97] Yau had proposed that, rather than holomorphic vector fields on the manifold itself, it should be relevant to study the deformations of projective embeddings of Kähler manifolds under holomorphic vector fields on projective space. This idea was modified by Tian, introducing the notion of K-stability and showing that any Kähler-Einstein manifold must be K-stable.[T97]

Simon Donaldson, in 2002, modified and extended Tian's definition of K-stability.[10] The conjecture that K-stability would be sufficient to ensure the existence of a Kähler-Einstein metric became known as the Yau-Tian-Donaldson conjecture. In 2015, Xiuxiong Chen, Donaldson, and Song Sun, published a proof of the conjecture, receiving the Oswald Veblen Prize in Geometry for their work.[11][12][13] Tian published a proof of the conjecture in the same year, although Chen, Donaldson, and Sun have accused Tian of academic and mathematical misconduct over his paper.[T15][14][15]

Kähler geometry edit

In one of his first articles, Tian studied the space of Calabi-Yau metrics on a Kähler manifold.[T87a] He showed that any infinitesimal deformation of Calabi-Yau structure can be 'integrated' to a one-parameter family of Calabi-Yau metrics; this proves that the "moduli space" of Calabi-Yau metrics on the given manifold has the structure of a smooth manifold. This was also studied earlier by Andrey Todorov, and the result is known as the Tian−Todorov theorem.[16] As an application, Tian found a formula for the Weil-Petersson metric on the moduli space of Calabi-Yau metrics in terms of the period mapping.[T87a][17]

Motivated by the Kähler-Einstein problem and a conjecture of Yau relating to Bergman metrics, Tian studied the following problem. Let L be a line bundle over a Kähler manifold M, and fix a hermitian bundle metric whose curvature form is a Kähler form on M. Suppose that for sufficiently large m, an orthonormal set of holomorphic sections of the line bundle Lm defines a projective embedding of M. One can pull back the Fubini-Study metric to define a sequence of metrics on M as m increases. Tian showed that a certain rescaling of this sequence will necessarily converge in the C2 topology to the original Kähler metric.[T90a] The refined asymptotics of this sequence were taken up in a number of influential subsequent papers by other authors, and are particularly important in Simon Donaldson's program on extremal metrics.[18][19][20][21][22] The approximability of a Kähler metric by Kähler metrics induced from projective embeddings is also relevant to Yau's picture of the Yau-Tian-Donaldson conjecture, as indicated above.

In a highly technical article, Xiuxiong Chen and Tian studied the regularity theory of certain complex Monge-Ampère equations, with applications to the study of the geometry of extremal Kähler metrics.[CT08] Although their paper has been very widely cited, Julius Ross and David Witt Nyström found counterexamples to the regularity results of Chen and Tian in 2015.[23] It is not clear which results of Chen and Tian's article remain valid.

Gromov-Witten theory edit

Pseudoholomorphic curves were shown by Mikhail Gromov in 1985 to be powerful tools in symplectic geometry.[24] In 1991, Edward Witten conjectured a use of Gromov's theory to define enumerative invariants.[25] Tian and Yongbin Ruan found the details of such a construction, proving that the various intersections of the images of pseudo-holomorphic curves is independent of many choices, and in particular gives an associative multilinear mapping on the homology of certain symplectic manifolds.[RT95] This structure is known as quantum cohomology; a contemporaneous and similarly influential approach is due to Dusa McDuff and Dietmar Salamon.[26] Ruan and Tian's results are in a somewhat more general setting.

With Jun Li, Tian gave a purely algebraic adaptation of these results to the setting of algebraic varieties.[LT98b] This was done at the same time as Kai Behrend and Barbara Fantechi, using a different approach.[27]

Li and Tian then adapted their algebro-geometric work back to the analytic setting in symplectic manifolds, extending the earlier work of Ruan and Tian.[LT98a] Tian and Gang Liu made use of this work to prove the well-known Arnold conjecture on the number of fixed points of Hamiltonian diffeomorphisms.[LT98c] However, these papers of Li-Tian and Liu-Tian on symplectic Gromov-Witten theory have been criticized by Dusa McDuff and Katrin Wehrheim as being incomplete or incorrect, saying that Li and Tian's article [LT98a] "lacks almost all detail" on certain points and that Liu and Tian's article [LT98c] has "serious analytic errors."[28]

Geometric analysis edit

In 1995, Tian and Weiyue Ding studied the harmonic map heat flow of a two-dimensional closed Riemannian manifold into a closed Riemannian manifold N.[DT95] In a seminal 1985 work, following the 1982 breakthrough of Jonathan Sacks and Karen Uhlenbeck, Michael Struwe had studied this problem and showed that there is a weak solution which exists for all positive time. Furthermore, Struwe showed that the solution u is smooth away from finitely many spacetime points; given any sequence of spacetime points at which the solution is smooth and which converge to a given singular point (p, T), one can perform some rescalings to (subsequentially) define a finite number of harmonic maps from the round 2-dimensional sphere into N, called "bubbles." Ding and Tian proved a certain "energy quantization," meaning that the defect between the Dirichlet energy of u(T) and the limit of the Dirichlet energy of u(t) as t approaches T is exactly measured by the sum of the Dirichlet energies of the bubbles. Such results are significant in geometric analysis, following the original energy quantization result of Yum-Tong Siu and Shing-Tung Yau in their proof of the Frankel conjecture.[29] The analogous problem for harmonic maps, as opposed to Ding and Tian's consideration of the harmonic map flow, was considered by Changyou Wang around the same time.[30]

A major paper of Tian's dealt with the Yang–Mills equations.[T00a] In addition to extending much of Karen Uhlenbeck's analysis to higher dimensions, he studied the interaction of Yang-Mills theory with calibrated geometry. Uhlenbeck had shown in the 1980s that, when given a sequence of Yang-Mills connections of uniformly bounded energy, they will converge smoothly on the complement of a subset of codimension at least four, known as the complement of the "singular set". Tian showed that the singular set is a rectifiable set. In the case that the manifold is equipped with a calibration, one can restrict interest to the Yang-Mills connections which are self-dual relative to the calibration. In this case, Tian showed that the singular set is calibrated. For instance, the singular set of a sequence of hermitian Yang-Mills connections of uniformly bounded energy will be a holomorphic cycle. This is a significant geometric feature of the analysis of Yang-Mills connections.

Ricci flow edit

In 2006, Tian and Zhou Zhang studied the Ricci flow in the special setting of closed Kähler manifolds.[TZ06] Their principal achievement was to show that the maximal time of existence can be characterized in purely cohomological terms. This represents one sense in which the Kähler-Ricci flow is significantly simpler than the usual Ricci flow, where there is no (known) computation of the maximal time of existence from a given geometric context. Tian and Zhang's proof consists of a use of the scalar maximum principle as applied to various geometric evolution equations, in terms of a Kähler potential as parametrized by a linear deformation of forms which is cohomologous to the Kähler-Ricci flow itself. In a notable work with Jian Song, Tian analyzed the Kähler Ricci flow on certain two-dimensional complex manifolds.[ST07]

In 2002 and 2003, Grigori Perelman posted three papers on the arXiv which purported to prove the Poincaré conjecture and Geometrization conjecture in the field of three-dimensional geometric topology.[31][32][33] Perelman's papers were immediately acclaimed for many of their novel ideas and results, although the technical details of many of his arguments were seen as hard to verify. In collaboration with John Morgan, Tian published an exposition of Perelman's papers in 2007, filling in many of the details.[MT07] Other expositions, which have also been widely studied, were written by Huai-Dong Cao and Xi-Ping Zhu, and by Bruce Kleiner and John Lott.[34][35] Morgan and Tian's exposition is the only of the three to deal with Perelman's third paper,[33] which is irrelevant for analysis of the geometrization conjecture but uses curve-shortening flow to provide a simpler argument for the special case of the Poincaré conjecture. Eight years after the publication of Morgan and Tian's book, Abbas Bahri pointed to part of their exposition of this paper to be in error, having relied upon incorrect computations of evolution equations.[36] The error, which dealt with details not present in Perelman's paper, was soon after amended by Morgan and Tian.[37]

In collaboration with Nataša Šešum, Tian also published an exposition of Perelman's work on the Ricci flow of Kähler manifolds, which Perelman did not publish in any form.[38]

Selected publications edit

Research articles.

T87a.
Tian, Gang (1987). "Smoothness of the universal deformation space of compact Calabi–Yau manifolds and its Petersson–Weil metric". In Yau, S.-T. (ed.). Mathematical aspects of string theory. Conference held at the University of California, San Diego (July 21–August 1, 1986). Advanced Series in Mathematical Physics. Vol. 1. Singapore: World Scientific Publishing Co. pp. 629–646. doi:10.1142/9789812798411_0029. ISBN 9971-50-273-9. MR 0915841.
T87b.
Tian, Gang (1987). "On Kähler–Einstein metrics on certain Kähler manifolds with c1(M) > 0". Inventiones Mathematicae. 89 (2): 225–246. doi:10.1007/BF01389077. MR 0894378. S2CID 122352133.
TY87.
Tian, Gang; Yau, Shing-Tung (1987). "Kähler–Einstein metrics on complex surfaces with C1 > 0". Communications in Mathematical Physics. 112 (1): 175–203. doi:10.1007/BF01217685. MR 0904143. S2CID 121216755.
T90a.
Tian, Gang (1990). "On a set of polarized Kähler metrics on algebraic manifolds". Journal of Differential Geometry. 32 (1): 99–130. doi:10.4310/jdg/1214445039. MR 1064867.
T90b.
Tian, G. (1990). "On Calabi's conjecture for complex surfaces with positive first Chern class". Inventiones Mathematicae. 101 (1): 101–172}. Bibcode:1990InMat.101..101T. doi:10.1007/BF01231499. MR 1055713. S2CID 59419559.
TY90.
Tian, G.; Yau, Shing-Tung (1990). "Complete Kähler manifolds with zero Ricci curvature. I". Journal of the American Mathematical Society. 3 (3): 579–609. doi:10.1090/S0894-0347-1990-1040196-6. MR 1040196.
TY91.
Tian, Gang; Yau, Shing-Tung (1991). "Complete Kähler manifolds with zero Ricci curvature. II". Inventiones Mathematicae. 106 (1): 27–60. Bibcode:1991InMat.106...27T. doi:10.1007/BF01243902. MR 1123371. S2CID 122638262.
DT92.
Ding, Wei Yue; Tian, Gang (1992). "Kähler–Einstein metrics and the generalized Futaki invariant". Inventiones Mathematicae. 110: 315–335. Bibcode:1992InMat.110..315D. doi:10.1007/BF01231335. MR 1185586. S2CID 59332400.
DT95.
Ding, Weiyue; Tian, Gang (1995). "Energy identity for a class of approximate harmonic maps from surfaces". Communications in Analysis and Geometry. 3 (3–4): 543–554. doi:10.4310/CAG.1995.v3.n4.a1. MR 1371209.
RT95.
Ruan, Yongbin; Tian, Gang (1995). "A mathematical theory of quantum cohomology". Journal of Differential Geometry. 42 (2): 259–367. doi:10.4310/jdg/1214457234. MR 1366548.
ST97.
Siebert, Bernd; Tian, Gang (1997). "On quantum cohomology rings of Fano manifolds and a formula of Vafa and Intriligator". Asian Journal of Mathematics. 1 (4): 679–695. doi:10.4310/AJM.1997.v1.n4.a2. MR 1621570. S2CID 14494725.
T97.
Tian, Gang (1997). "Kähler–Einstein metrics with positive scalar curvature". Inventiones Mathematicae. 130 (1): 1–37. Bibcode:1997InMat.130....1T. doi:10.1007/s002220050176. MR 1471884. S2CID 122529381.
LT98a.
Li, Jun; Tian, Gang (1998). "Virtual moduli cycles and Gromov–Witten invariants of general symplectic manifolds". In Stern, Ronald J. (ed.). Topics in symplectic 4-manifolds. 1st International Press Lectures presented at the University of California, Irvine (March 28–30, 1996). First International Press Lecture Series. Vol. I. Cambridge, MA: International Press. pp. 47–83. arXiv:alg-geom/9608032. ISBN 1-57146-019-5. MR 1635695.
LT98b.
Li, Jun; Tian, Gang (1998). "Virtual moduli cycles and Gromov–Witten invariants of algebraic varieties". Journal of the American Mathematical Society. 11 (1): 119–174. doi:10.1090/S0894-0347-98-00250-1. MR 1467172. S2CID 15201721.
LT98c.
Liu, Gang; Tian, Gang (1998). "Floer homology and Arnold conjecture". Journal of Differential Geometry. 49 (1): 1–74. doi:10.4310/jdg/1214460936. MR 1642105.
T00a.
Tian, Gang (2000). "Gauge theory and calibrated geometry. I". Annals of Mathematics. Second Series. 151 (1): 193–268. arXiv:math/0010015. doi:10.2307/121116. JSTOR 121116. MR 1745014.
TZ06.
Tian, Gang; Zhang, Zhou (2006). "On the Kähler–Ricci flow on projective manifolds of general type". Chinese Annals of Mathematics, Series B. 27 (2): 179–192. CiteSeerX 10.1.1.116.5906. doi:10.1007/s11401-005-0533-x. MR 2243679. S2CID 16476473.
ST07.
Song, Jian; Tian, Gang (2007). "The Kähler–Ricci flow on surfaces of positive Kodaira dimension". Inventiones Mathematicae. 17 (3): 609–653. arXiv:math/0602150. Bibcode:2007InMat.170..609S. doi:10.1007/s00222-007-0076-8. MR 2357504. S2CID 735225.
CT08.
Chen, X. X.; Tian, G. (2008). "Geometry of Kähler metrics and foliations by holomorphic discs". Publications Mathématiques de l'Institut des Hautes Études Scientifiques. 107: 1–107. arXiv:math/0507148. doi:10.1007/s10240-008-0013-4. MR 2434691. S2CID 119699845.
T15.
Tian, Gang (2015). "K-stability and Kähler–Einstein metrics". Communications on Pure and Applied Mathematics. 68 (7): 1085–1156. arXiv:1211.4669. doi:10.1002/cpa.21578. MR 3352459. S2CID 119303358. (Erratum: doi:10.1002/cpa.21612)

Books.

T00b.
Tian, Gang (2000). Canonical metrics in Kähler geometry. Lectures in Mathematics ETH Zürich. Notes taken by Meike Akveld. Basel: Birkhäuser Verlag. doi:10.1007/978-3-0348-8389-4. ISBN 3-7643-6194-8. MR 1787650.
MT07.
Morgan, John; Tian, Gang (2007). Ricci flow and the Poincaré conjecture. Clay Mathematics Monographs. Vol. 3. Cambridge, MA: Clay Mathematics Institute. arXiv:math/0607607. ISBN 978-0-8218-4328-4. MR 2334563.

Morgan, John; Tian, Gang (2015). "Correction to Section 19.2 of Ricci Flow and the Poincare Conjecture". arXiv:1512.00699 [math.DG].
MT14.
Morgan, John; Tian, Gang (2014). The geometrization conjecture. Clay Mathematics Monographs. Vol. 5. Cambridge, MA: Clay Mathematics Institute. ISBN 978-0-8218-5201-9. MR 3186136.

References edit

  1. ^ "1996 Oswald Veblen Prize" (PDF). AMS. 1996.
  2. ^ Governing Board, Beijing International Center for Mathematical Research, http://www.bicmr.org/content/page/27.html
  3. ^ History of School of Mathematical Sciences, Peking University, http://www.math.pku.edu.cn/static/lishiyange.html
  4. ^ "ICTP - Governance". www.ictp.it. Retrieved 2018-05-28.
  5. ^ http://www.ams.org/notices/201304/rnoti-p480.pdf[bare URL PDF]
  6. ^ Anderson, Michael T. Ricci curvature bounds and Einstein metrics on compact manifolds. J. Amer. Math. Soc. 2 (1989), no. 3, 455–490.
  7. ^ Bando, Shigetoshi; Kasue, Atsushi; Nakajima, Hiraku. On a construction of coordinates at infinity on manifolds with fast curvature decay and maximal volume growth. Invent. Math. 97 (1989), no. 2, 313–349.
  8. ^ Anderson, Michael T. Convergence and rigidity of manifolds under Ricci curvature bounds. Invent. Math. 102 (1990), no. 2, 429–445.
  9. ^ Futaki, A. An obstruction to the existence of Einstein Kähler metrics. Invent. Math. 73 (1983), no. 3, 437–443.
  10. ^ Donaldson, S.K. Scalar curvature and stability of toric varieties. J. Differential Geom. 62 (2002), no. 2, 289–349.
  11. ^ Chen, Xiuxiong; Donaldson, Simon; Sun, Song. Kähler-Einstein metrics on Fano manifolds. I: Approximation of metrics with cone singularities. J. Amer. Math. Soc. 28 (2015), no. 1, 183–197.
  12. ^ Chen, Xiuxiong; Donaldson, Simon; Sun, Song. Kähler-Einstein metrics on Fano manifolds. II: Limits with cone angle less than 2π. J. Amer. Math. Soc. 28 (2015), no. 1, 199–234.
  13. ^ Chen, Xiuxiong; Donaldson, Simon; Sun, Song. Kähler-Einstein metrics on Fano manifolds. III: Limits as cone angle approaches 2π and completion of the main proof. J. Amer. Math. Soc. 28 (2015), no. 1, 235–278.
  14. ^ Xiuxiong Chen, Simon, Donaldson, and Song Sun. On some recent developments in Kähler geometry.
  15. ^ Gang Tian. Response to CDS.
  16. ^ Todorov, Andrey N. The Weil-Petersson geometry of the moduli space of SU(n ≥ 3) (Calabi-Yau) manifolds. I. Comm. Math. Phys. 126 (1989), no. 2, 325–346.
  17. ^ Huybrechts, Daniel. Complex geometry. An introduction. [Chapter 6.] Universitext. Springer-Verlag, Berlin, 2005. xii+309 pp. ISBN 3-540-21290-6
  18. ^ Zelditch, Steve. Szegő kernels and a theorem of Tian. Internat. Math. Res. Notices 1998, no. 6, 317–331.
  19. ^ Catlin, David. The Bergman kernel and a theorem of Tian. Analysis and geometry in several complex variables (Katata, 1997), 1–23, Trends Math., Birkhäuser Boston, Boston, MA, 1999.
  20. ^ Lu, Zhiqin. On the lower order terms of the asymptotic expansion of Tian-Yau-Zelditch. Amer. J. Math. 122 (2000), no. 2, 235–273.
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  22. ^ Donaldson, S.K. Lower bounds on the Calabi functional. J. Differential Geom. 70 (2005), no. 3, 453–472.
  23. ^ Ross, Julius; Nyström, David Witt. Harmonic discs of solutions to the complex homogeneous Monge-Ampère equation. Publ. Math. Inst. Hautes Études Sci. 122 (2015), 315–335.
  24. ^ Gromov, M. Pseudo holomorphic curves in symplectic manifolds. Invent. Math. 82 (1985), no. 2, 307–347.
  25. ^ Witten, Edward. Two-dimensional gravity and intersection theory on moduli space. Surveys in differential geometry (Cambridge, MA, 1990), 243–310, Lehigh Univ., Bethlehem, PA, 1991.
  26. ^ McDuff, Dusa; Salamon, Dietmar. J-holomorphic curves and quantum cohomology. University Lecture Series, 6. American Mathematical Society, Providence, RI, 1994. viii+207 pp. ISBN 0-8218-0332-8
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  28. ^ McDuff, Dusa; Wehrheim, Katrin. The fundamental class of smooth Kuranishi atlases with trivial isotropy. J. Topol. Anal. 10 (2018), no. 1, 71–243.
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  30. ^ Wang, Changyou. Bubble phenomena of certain Palais-Smale sequences from surfaces to general targets. Houston J. Math. 22 (1996), no. 3, 559–590.
  31. ^ Grisha Perelman. The entropy formula for the Ricci flow and its geometric applications. arXiv:math/0211159
  32. ^ Grisha Perelman. Ricci flow with surgery on three-manifolds. arXiv:math/0303109
  33. ^ a b Grisha Perelman. Finite extinction time for the solutions to the Ricci flow on certain three-manifolds. arXiv:math/0307245
  34. ^ 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.
  35. ^ Kleiner, Bruce; Lott, John. Notes on Perelman's papers. Geom. Topol. 12 (2008), no. 5, 2587–2855.
  36. ^ Bahri, Abbas. Five gaps in mathematics. Adv. Nonlinear Stud. 15 (2015), no. 2, 289–319.
  37. ^ John Morgan and Gang Tian. Correction to Section 19.2 of Ricci Flow and the Poincare Conjecture. arXiv:1512.00699 (2015)
  38. ^ Sesum, Natasa; Tian, Gang. Bounding scalar curvature and diameter along the Kähler Ricci flow (after Perelman). J. Inst. Math. Jussieu 7 (2008), no. 3, 575–587.

External links edit

November 23, 2023
tian, gang, this, biography, living, person, needs, additional, citations, verification, please, help, adding, reliable, sources, contentious, material, about, living, persons, that, unsourced, poorly, sourced, must, removed, immediately, from, article, talk, . This biography of a living person needs additional citations for verification Please help by adding reliable sources Contentious material about living persons that is unsourced or poorly sourced must be removed immediately from the article and its talk page especially if potentially libelous Find sources Tian Gang news newspapers books scholar JSTOR June 2014 template removal help In this Chinese name the family name is Tian Tian Gang Chinese 田刚 born November 24 1958 1 is a Chinese mathematician He is a professor of mathematics at Peking University and Higgins Professor Emeritus at Princeton University He is known for contributions to the mathematical fields of Kahler geometry Gromov Witten theory and geometric analysis Tian GangTian at Oberwolfach in 2005Born 1958 11 24 24 November 1958 age 64 Nanjing Jiangsu ChinaNationalityChineseAlma materHarvard UniversityPeking UniversityNanjing UniversityKnown forYau Tian Donaldson conjectureK stabilityK stability of Fano varietiesAwardsVeblen Prize 1996 Alan T Waterman Award 1994 Scientific careerFieldsMathematicsInstitutionsPrinceton UniversityPeking UniversityThesisKahler Metrics on Algebraic Manifolds 1988 Doctoral advisorShing Tung YauDoctoral studentsNatasa SesumWei DongyiChinese nameTraditional Chinese田剛Simplified Chinese田刚TranscriptionsStandard MandarinHanyu PinyinTian GangAs of 2020 he is the Vice Chairman of the China Democratic League and the President of the Chinese Mathematical Society From 2017 to 2019 he served as the Vice President of Peking University Contents 1 Biography 2 Mathematical contributions 2 1 The Kahler Einstein problem 2 2 Kahler geometry 2 3 Gromov Witten theory 2 4 Geometric analysis 2 5 Ricci flow 3 Selected publications 4 References 5 External linksBiography editTian was born in Nanjing Jiangsu China He qualified in the second college entrance exam after Cultural Revolution in 1978 He graduated from Nanjing University in 1982 and received a master s degree from Peking University in 1984 In 1988 he received a Ph D in mathematics from Harvard University under the supervision of Shing Tung Yau In 1998 he was appointed as a Cheung Kong Scholar professor at Peking University Later his appointment was changed to Cheung Kong Scholar chair professorship He was a professor of mathematics at the Massachusetts Institute of Technology from 1995 to 2006 holding the chair of Simons Professor of Mathematics from 1996 His employment at Princeton started from 2003 and was later appointed the Higgins Professor of Mathematics Starting 2005 he has been the director of the Beijing International Center for Mathematical Research BICMR 2 from 2013 to 2017 he was the Dean of School of Mathematical Sciences at Peking University 3 He and John Milnor are Senior Scholars of the Clay Mathematics Institute CMI In 2011 Tian became director of the Sino French Research Program in Mathematics at the Centre national de la recherche scientifique CNRS in Paris In 2010 he became scientific consultant for the International Center for Theoretical Physics in Trieste Italy 4 Tian has served on many committees including for the Abel Prize and the Leroy P Steele Prize 5 He is a member of the editorial boards of many journals including Advances in Mathematics and the Journal of Geometric Analysis In the past he has been on the editorial boards of Annals of Mathematics and the Journal of the American Mathematical Society Among his awards and honors Sloan Research Fellowship 1991 1993 Alan T Waterman Award 1994 Oswald Veblen Prize in Geometry 1996 Elected to the Chinese Academy of Sciences 2001 Elected to the American Academy of Arts and Sciences 2004 Since at least 2013 he has been heavily involved in Chinese politics serving as the Vice Chairman of the China Democratic League the second most populous political party in China Mathematical contributions editThe Kahler Einstein problem edit Tian is well known for his contributions to Kahler geometry and in particular to the study of Kahler Einstein metrics Shing Tung Yau in his renowned resolution of the Calabi conjecture had settled the case of closed Kahler manifolds with nonpositive first Chern class His work in applying the method of continuity showed that C0 control of the Kahler potentials would suffice to prove existence of Kahler Einstein metrics on closed Kahler manifolds with positive first Chern class also known as Fano manifolds Tian and Yau extended Yau s analysis of the Calabi conjecture to noncompact settings where they obtained partial results TY90 They also extended their work to allow orbifold singularities TY91 Tian introduced the a invariant which is essentially the optimal constant in the Moser Trudinger inequality when applied to Kahler potentials with a supremal value of 0 He showed that if the a invariant is sufficiently large i e if a sufficiently strong Moser Trudinger inequality holds then C0 control in Yau s method of continuity could be achieved T87b This was applied to demonstrate new examples of Kahler Einstein surfaces The case of Kahler surfaces was revisited by Tian in 1990 giving a complete resolution of the Kahler Einstein problem in that context T90b The main technique was to study the possible geometric degenerations of a sequence of Kahler Einstein metrics as detectable by the Gromov Hausdorff convergence Tian adapted many of the technical innovations of Karen Uhlenbeck as developed for Yang Mills connections to the setting of Kahler metrics Some similar and influential work in the Riemannian setting was done in 1989 and 1990 by Michael Anderson Shigetoshi Bando Atsushi Kasue and Hiraku Nakajima 6 7 8 Tian s most renowned contribution to the Kahler Einstein problem came in 1997 Yau had conjectured in the 1980s based partly in analogy to the Donaldson Uhlenbeck Yau theorem that existence of a Kahler Einstein metric should correspond to stability of the underlying Kahler manifold in a certain sense of geometric invariant theory It was generally understood especially following work of Akito Futaki 9 that the existence of holomorphic vector fields should act as an obstruction to the existence of Kahler Einstein metrics Tian and Wei Yue Ding established that this obstruction is not sufficient within the class of Kahler orbifolds DT92 Tian in his 1997 article gave concrete examples of Kahler manifolds rather than orbifolds which had no holomorphic vector fields and also no Kahler Einstein metrics showing that the desired criterion lies deeper T97 Yau had proposed that rather than holomorphic vector fields on the manifold itself it should be relevant to study the deformations of projective embeddings of Kahler manifolds under holomorphic vector fields on projective space This idea was modified by Tian introducing the notion of K stability and showing that any Kahler Einstein manifold must be K stable T97 Simon Donaldson in 2002 modified and extended Tian s definition of K stability 10 The conjecture that K stability would be sufficient to ensure the existence of a Kahler Einstein metric became known as the Yau Tian Donaldson conjecture In 2015 Xiuxiong Chen Donaldson and Song Sun published a proof of the conjecture receiving the Oswald Veblen Prize in Geometry for their work 11 12 13 Tian published a proof of the conjecture in the same year although Chen Donaldson and Sun have accused Tian of academic and mathematical misconduct over his paper T15 14 15 Kahler geometry edit In one of his first articles Tian studied the space of Calabi Yau metrics on a Kahler manifold T87a He showed that any infinitesimal deformation of Calabi Yau structure can be integrated to a one parameter family of Calabi Yau metrics this proves that the moduli space of Calabi Yau metrics on the given manifold has the structure of a smooth manifold This was also studied earlier by Andrey Todorov and the result is known as the Tian Todorov theorem 16 As an application Tian found a formula for the Weil Petersson metric on the moduli space of Calabi Yau metrics in terms of the period mapping T87a 17 Motivated by the Kahler Einstein problem and a conjecture of Yau relating to Bergman metrics Tian studied the following problem Let L be a line bundle over a Kahler manifold M and fix a hermitian bundle metric whose curvature form is a Kahler form on M Suppose that for sufficiently large m an orthonormal set of holomorphic sections of the line bundle L m defines a projective embedding of M One can pull back the Fubini Study metric to define a sequence of metrics on M as m increases Tian showed that a certain rescaling of this sequence will necessarily converge in the C2 topology to the original Kahler metric T90a The refined asymptotics of this sequence were taken up in a number of influential subsequent papers by other authors and are particularly important in Simon Donaldson s program on extremal metrics 18 19 20 21 22 The approximability of a Kahler metric by Kahler metrics induced from projective embeddings is also relevant to Yau s picture of the Yau Tian Donaldson conjecture as indicated above In a highly technical article Xiuxiong Chen and Tian studied the regularity theory of certain complex Monge Ampere equations with applications to the study of the geometry of extremal Kahler metrics CT08 Although their paper has been very widely cited Julius Ross and David Witt Nystrom found counterexamples to the regularity results of Chen and Tian in 2015 23 It is not clear which results of Chen and Tian s article remain valid Gromov Witten theory edit Pseudoholomorphic curves were shown by Mikhail Gromov in 1985 to be powerful tools in symplectic geometry 24 In 1991 Edward Witten conjectured a use of Gromov s theory to define enumerative invariants 25 Tian and Yongbin Ruan found the details of such a construction proving that the various intersections of the images of pseudo holomorphic curves is independent of many choices and in particular gives an associative multilinear mapping on the homology of certain symplectic manifolds RT95 This structure is known as quantum cohomology a contemporaneous and similarly influential approach is due to Dusa McDuff and Dietmar Salamon 26 Ruan and Tian s results are in a somewhat more general setting With Jun Li Tian gave a purely algebraic adaptation of these results to the setting of algebraic varieties LT98b This was done at the same time as Kai Behrend and Barbara Fantechi using a different approach 27 Li and Tian then adapted their algebro geometric work back to the analytic setting in symplectic manifolds extending the earlier work of Ruan and Tian LT98a Tian and Gang Liu made use of this work to prove the well known Arnold conjecture on the number of fixed points of Hamiltonian diffeomorphisms LT98c However these papers of Li Tian and Liu Tian on symplectic Gromov Witten theory have been criticized by Dusa McDuff and Katrin Wehrheim as being incomplete or incorrect saying that Li and Tian s article LT98a lacks almost all detail on certain points and that Liu and Tian s article LT98c has serious analytic errors 28 Geometric analysis edit In 1995 Tian and Weiyue Ding studied the harmonic map heat flow of a two dimensional closed Riemannian manifold into a closed Riemannian manifold N DT95 In a seminal 1985 work following the 1982 breakthrough of Jonathan Sacks and Karen Uhlenbeck Michael Struwe had studied this problem and showed that there is a weak solution which exists for all positive time Furthermore Struwe showed that the solution u is smooth away from finitely many spacetime points given any sequence of spacetime points at which the solution is smooth and which converge to a given singular point p T one can perform some rescalings to subsequentially define a finite number of harmonic maps from the round 2 dimensional sphere into N called bubbles Ding and Tian proved a certain energy quantization meaning that the defect between the Dirichlet energy of u T and the limit of the Dirichlet energy of u t as t approaches T is exactly measured by the sum of the Dirichlet energies of the bubbles Such results are significant in geometric analysis following the original energy quantization result of Yum Tong Siu and Shing Tung Yau in their proof of the Frankel conjecture 29 The analogous problem for harmonic maps as opposed to Ding and Tian s consideration of the harmonic map flow was considered by Changyou Wang around the same time 30 A major paper of Tian s dealt with the Yang Mills equations T00a In addition to extending much of Karen Uhlenbeck s analysis to higher dimensions he studied the interaction of Yang Mills theory with calibrated geometry Uhlenbeck had shown in the 1980s that when given a sequence of Yang Mills connections of uniformly bounded energy they will converge smoothly on the complement of a subset of codimension at least four known as the complement of the singular set Tian showed that the singular set is a rectifiable set In the case that the manifold is equipped with a calibration one can restrict interest to the Yang Mills connections which are self dual relative to the calibration In this case Tian showed that the singular set is calibrated For instance the singular set of a sequence of hermitian Yang Mills connections of uniformly bounded energy will be a holomorphic cycle This is a significant geometric feature of the analysis of Yang Mills connections Ricci flow edit In 2006 Tian and Zhou Zhang studied the Ricci flow in the special setting of closed Kahler manifolds TZ06 Their principal achievement was to show that the maximal time of existence can be characterized in purely cohomological terms This represents one sense in which the Kahler Ricci flow is significantly simpler than the usual Ricci flow where there is no known computation of the maximal time of existence from a given geometric context Tian and Zhang s proof consists of a use of the scalar maximum principle as applied to various geometric evolution equations in terms of a Kahler potential as parametrized by a linear deformation of forms which is cohomologous to the Kahler Ricci flow itself In a notable work with Jian Song Tian analyzed the Kahler Ricci flow on certain two dimensional complex manifolds ST07 In 2002 and 2003 Grigori Perelman posted three papers on the arXiv which purported to prove the Poincare conjecture and Geometrization conjecture in the field of three dimensional geometric topology 31 32 33 Perelman s papers were immediately acclaimed for many of their novel ideas and results although the technical details of many of his arguments were seen as hard to verify In collaboration with John Morgan Tian published an exposition of Perelman s papers in 2007 filling in many of the details MT07 Other expositions which have also been widely studied were written by Huai Dong Cao and Xi Ping Zhu and by Bruce Kleiner and John Lott 34 35 Morgan and Tian s exposition is the only of the three to deal with Perelman s third paper 33 which is irrelevant for analysis of the geometrization conjecture but uses curve shortening flow to provide a simpler argument for the special case of the Poincare conjecture Eight years after the publication of Morgan and Tian s book Abbas Bahri pointed to part of their exposition of this paper to be in error having relied upon incorrect computations of evolution equations 36 The error which dealt with details not present in Perelman s paper was soon after amended by Morgan and Tian 37 In collaboration with Natasa Sesum Tian also published an exposition of Perelman s work on the Ricci flow of Kahler manifolds which Perelman did not publish in any form 38 Selected publications editResearch articles T87a Tian Gang 1987 Smoothness of the universal deformation space of compact Calabi Yau manifolds and its Petersson Weil metric In Yau S T ed Mathematical aspects of string theory Conference held at the University of California San Diego July 21 August 1 1986 Advanced Series in Mathematical Physics Vol 1 Singapore World Scientific Publishing Co pp 629 646 doi 10 1142 9789812798411 0029 ISBN 9971 50 273 9 MR 0915841 T87b Tian Gang 1987 On Kahler Einstein metrics on certain Kahler manifolds with c1 M gt 0 Inventiones Mathematicae 89 2 225 246 doi 10 1007 BF01389077 MR 0894378 S2CID 122352133 TY87 Tian Gang Yau Shing Tung 1987 Kahler Einstein metrics on complex surfaces with C1 gt 0 Communications in Mathematical Physics 112 1 175 203 doi 10 1007 BF01217685 MR 0904143 S2CID 121216755 T90a Tian Gang 1990 On a set of polarized Kahler metrics on algebraic manifolds Journal of Differential Geometry 32 1 99 130 doi 10 4310 jdg 1214445039 MR 1064867 T90b Tian G 1990 On Calabi s conjecture for complex surfaces with positive first Chern class Inventiones Mathematicae 101 1 101 172 Bibcode 1990InMat 101 101T doi 10 1007 BF01231499 MR 1055713 S2CID 59419559 TY90 Tian G Yau Shing Tung 1990 Complete Kahler manifolds with zero Ricci curvature I Journal of the American Mathematical Society 3 3 579 609 doi 10 1090 S0894 0347 1990 1040196 6 MR 1040196 TY91 Tian Gang Yau Shing Tung 1991 Complete Kahler manifolds with zero Ricci curvature II Inventiones Mathematicae 106 1 27 60 Bibcode 1991InMat 106 27T doi 10 1007 BF01243902 MR 1123371 S2CID 122638262 DT92 Ding Wei Yue Tian Gang 1992 Kahler Einstein metrics and the generalized Futaki invariant Inventiones Mathematicae 110 315 335 Bibcode 1992InMat 110 315D doi 10 1007 BF01231335 MR 1185586 S2CID 59332400 DT95 Ding Weiyue Tian Gang 1995 Energy identity for a class of approximate harmonic maps from surfaces Communications in Analysis and Geometry 3 3 4 543 554 doi 10 4310 CAG 1995 v3 n4 a1 MR 1371209 RT95 Ruan Yongbin Tian Gang 1995 A mathematical theory of quantum cohomology Journal of Differential Geometry 42 2 259 367 doi 10 4310 jdg 1214457234 MR 1366548 ST97 Siebert Bernd Tian Gang 1997 On quantum cohomology rings of Fano manifolds and a formula of Vafa and Intriligator Asian Journal of Mathematics 1 4 679 695 doi 10 4310 AJM 1997 v1 n4 a2 MR 1621570 S2CID 14494725 T97 Tian Gang 1997 Kahler Einstein metrics with positive scalar curvature Inventiones Mathematicae 130 1 1 37 Bibcode 1997InMat 130 1T doi 10 1007 s002220050176 MR 1471884 S2CID 122529381 LT98a Li Jun Tian Gang 1998 Virtual moduli cycles and Gromov Witten invariants of general symplectic manifolds In Stern Ronald J ed Topics in symplectic 4 manifolds 1st International Press Lectures presented at the University of California Irvine March 28 30 1996 First International Press Lecture Series Vol I Cambridge MA International Press pp 47 83 arXiv alg geom 9608032 ISBN 1 57146 019 5 MR 1635695 LT98b Li Jun Tian Gang 1998 Virtual moduli cycles and Gromov Witten invariants of algebraic varieties Journal of the American Mathematical Society 11 1 119 174 doi 10 1090 S0894 0347 98 00250 1 MR 1467172 S2CID 15201721 LT98c Liu Gang Tian Gang 1998 Floer homology and Arnold conjecture Journal of Differential Geometry 49 1 1 74 doi 10 4310 jdg 1214460936 MR 1642105 T00a Tian Gang 2000 Gauge theory and calibrated geometry I Annals of Mathematics Second Series 151 1 193 268 arXiv math 0010015 doi 10 2307 121116 JSTOR 121116 MR 1745014 TZ06 Tian Gang Zhang Zhou 2006 On the Kahler Ricci flow on projective manifolds of general type Chinese Annals of Mathematics Series B 27 2 179 192 CiteSeerX 10 1 1 116 5906 doi 10 1007 s11401 005 0533 x MR 2243679 S2CID 16476473 ST07 Song Jian Tian Gang 2007 The Kahler Ricci flow on surfaces of positive Kodaira dimension Inventiones Mathematicae 17 3 609 653 arXiv math 0602150 Bibcode 2007InMat 170 609S doi 10 1007 s00222 007 0076 8 MR 2357504 S2CID 735225 CT08 Chen X X Tian G 2008 Geometry of Kahler metrics and foliations by holomorphic discs Publications Mathematiques de l Institut des Hautes Etudes Scientifiques 107 1 107 arXiv math 0507148 doi 10 1007 s10240 008 0013 4 MR 2434691 S2CID 119699845 T15 Tian Gang 2015 K stability and Kahler Einstein metrics Communications on Pure and Applied Mathematics 68 7 1085 1156 arXiv 1211 4669 doi 10 1002 cpa 21578 MR 3352459 S2CID 119303358 Erratum doi 10 1002 cpa 21612 Books T00b Tian Gang 2000 Canonical metrics in Kahler geometry Lectures in Mathematics ETH Zurich Notes taken by Meike Akveld Basel Birkhauser Verlag doi 10 1007 978 3 0348 8389 4 ISBN 3 7643 6194 8 MR 1787650 MT07 Morgan John Tian Gang 2007 Ricci flow and the Poincare conjecture Clay Mathematics Monographs Vol 3 Cambridge MA Clay Mathematics Institute arXiv math 0607607 ISBN 978 0 8218 4328 4 MR 2334563 Morgan John Tian Gang 2015 Correction to Section 19 2 of Ricci Flow and the Poincare Conjecture arXiv 1512 00699 math DG MT14 Morgan John Tian Gang 2014 The geometrization conjecture Clay Mathematics Monographs Vol 5 Cambridge MA Clay Mathematics Institute ISBN 978 0 8218 5201 9 MR 3186136 References edit 1996 Oswald Veblen Prize PDF AMS 1996 Governing Board Beijing International Center for Mathematical Research http www bicmr org content page 27 html History of School of Mathematical Sciences Peking University http www math pku edu cn static lishiyange html ICTP Governance www ictp it Retrieved 2018 05 28 http www ams org notices 201304 rnoti p480 pdf bare URL PDF Anderson Michael T Ricci curvature bounds and Einstein metrics on compact manifolds J Amer Math Soc 2 1989 no 3 455 490 Bando Shigetoshi Kasue Atsushi Nakajima Hiraku On a construction of coordinates at infinity on manifolds with fast curvature decay and maximal volume growth Invent Math 97 1989 no 2 313 349 Anderson Michael T Convergence and rigidity of manifolds under Ricci curvature bounds Invent Math 102 1990 no 2 429 445 Futaki A An obstruction to the existence of Einstein Kahler metrics Invent Math 73 1983 no 3 437 443 Donaldson S K Scalar curvature and stability of toric varieties J Differential Geom 62 2002 no 2 289 349 Chen Xiuxiong Donaldson Simon Sun Song Kahler Einstein metrics on Fano manifolds I Approximation of metrics with cone singularities J Amer Math Soc 28 2015 no 1 183 197 Chen Xiuxiong Donaldson Simon Sun Song Kahler Einstein metrics on Fano manifolds II Limits with cone angle less than 2p J Amer Math Soc 28 2015 no 1 199 234 Chen Xiuxiong Donaldson Simon Sun Song Kahler Einstein metrics on Fano manifolds III Limits as cone angle approaches 2p and completion of the main proof J Amer Math Soc 28 2015 no 1 235 278 Xiuxiong Chen Simon Donaldson and Song Sun On some recent developments in Kahler geometry Gang Tian Response to CDS Todorov Andrey N The Weil Petersson geometry of the moduli space of SU n 3 Calabi Yau manifolds I Comm Math Phys 126 1989 no 2 325 346 Huybrechts Daniel Complex geometry An introduction Chapter 6 Universitext Springer Verlag Berlin 2005 xii 309 pp ISBN 3 540 21290 6 Zelditch Steve Szego kernels and a theorem of Tian Internat Math Res Notices 1998 no 6 317 331 Catlin David The Bergman kernel and a theorem of Tian Analysis and geometry in several complex variables Katata 1997 1 23 Trends Math Birkhauser Boston Boston MA 1999 Lu Zhiqin On the lower order terms of the asymptotic expansion of Tian Yau Zelditch Amer J Math 122 2000 no 2 235 273 Donaldson S K Scalar curvature and projective embeddings I J Differential Geom 59 2001 no 3 479 522 Donaldson S K Lower bounds on the Calabi functional J Differential Geom 70 2005 no 3 453 472 Ross Julius Nystrom David Witt Harmonic discs of solutions to the complex homogeneous Monge Ampere equation Publ Math Inst Hautes Etudes Sci 122 2015 315 335 Gromov M Pseudo holomorphic curves in symplectic manifolds Invent Math 82 1985 no 2 307 347 Witten Edward Two dimensional gravity and intersection theory on moduli space Surveys in differential geometry Cambridge MA 1990 243 310 Lehigh Univ Bethlehem PA 1991 McDuff Dusa Salamon Dietmar J holomorphic curves and quantum cohomology University Lecture Series 6 American Mathematical Society Providence RI 1994 viii 207 pp ISBN 0 8218 0332 8 Behrend K Fantechi B The intrinsic normal cone Invent Math 128 1997 no 1 45 88 McDuff Dusa Wehrheim Katrin The fundamental class of smooth Kuranishi atlases with trivial isotropy J Topol Anal 10 2018 no 1 71 243 Siu Yum Tong Yau Shing Tung Complete Kahler manifolds with nonpositive curvature of faster than quadratic decay Ann of Math 2 105 1977 no 2 225 264 Wang Changyou Bubble phenomena of certain Palais Smale sequences from surfaces to general targets Houston J Math 22 1996 no 3 559 590 Grisha Perelman The entropy formula for the Ricci flow and its geometric applications arXiv math 0211159 Grisha Perelman Ricci flow with surgery on three manifolds arXiv math 0303109 a b Grisha Perelman Finite extinction time for the solutions to the Ricci flow on certain three manifolds arXiv math 0307245 Cao Huai Dong Zhu Xi Ping A complete proof of the Poincare and geometrization conjectures application of the Hamilton Perelman theory of the Ricci flow Asian J Math 10 2006 no 2 165 492 Kleiner Bruce Lott John Notes on Perelman s papers Geom Topol 12 2008 no 5 2587 2855 Bahri Abbas Five gaps in mathematics Adv Nonlinear Stud 15 2015 no 2 289 319 John Morgan and Gang Tian Correction to Section 19 2 of Ricci Flow and the Poincare Conjecture arXiv 1512 00699 2015 Sesum Natasa Tian Gang Bounding scalar curvature and diameter along the Kahler Ricci flow after Perelman J Inst Math Jussieu 7 2008 no 3 575 587 External links editTian Gang at the Mathematics Genealogy Project Retrieved from https en wikipedia org w index php title Tian Gang amp oldid 1154497720, wikipedia, wiki, book, books, library,

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