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Grigori Perelman

January 26, 2023

In this name that follows Eastern Slavic naming conventions, the patronymic is Yakovlevich and the family name is Perelman.

Grigori Yakovlevich Perelman (Russian: Григорий Яковлевич Перельман, IPA: [ɡrʲɪˈɡorʲɪj ˈjakəvlʲɪvʲɪtɕ pʲɪrʲɪlʲˈman] (listen); born 13 June 1966) is a Russian mathematician who is known for his contributions to the fields of geometric analysis, Riemannian geometry, and geometric topology. He is widely regarded as one of the greatest living mathematicians.[1][2][3]

Grigori Perelman
Grigori Perelman in 1993
Born (1966-06-13) 13 June 1966 (age 56)
Leningrad, Soviet Union
NationalityRussian
CitizenshipRussia
Alma materLeningrad State University (PhD)
Known for
Awards
Scientific career
FieldsDifferential geometry
Geometric analysis
Geometric topology
ThesisSaddle Surfaces in Euclidean Spaces (1990)
Doctoral advisor

In the 1990s, partly in collaboration with Yuri Burago, Mikhael Gromov, and Anton Petrunin, he made contributions to the study of Alexandrov spaces. In 1994, he proved the soul conjecture in Riemannian geometry, which had been an open problem for the previous 20 years. In 2002 and 2003, he developed new techniques in the analysis of Ricci flow, and proved the Poincaré conjecture and Thurston's geometrization conjecture, the former of which had been a famous open problem in mathematics for the past century. The full details of Perelman's work were filled in and explained by various authors over the following several years.

In August 2006, Perelman was offered the Fields Medal[4] for "his contributions to geometry and his revolutionary insights into the analytical and geometric structure of the Ricci flow", but he declined the award, stating: "I'm not interested in money or fame; I don't want to be on display like an animal in a zoo."[5] On 22 December 2006, the scientific journal Science recognized Perelman's proof of the Poincaré conjecture as the scientific "Breakthrough of the Year", the first such recognition in the area of mathematics.[6]

On 18 March 2010, it was announced that he had met the criteria to receive the first Clay Millennium Prize[7] for resolution of the Poincaré conjecture. On 1 July 2010, he rejected the prize of one million dollars, saying that he considered the decision of the board of the Clay Institute to be unfair, in that his contribution to solving the Poincaré conjecture was no greater than that of Richard S. Hamilton, the mathematician who pioneered the Ricci flow partly with the aim of attacking the conjecture.[8][9] He had previously rejected the prestigious prize of the European Mathematical Society in 1996.[10]

Early life and education

Grigori Yakovlevich Perelman was born in Leningrad, Soviet Union (now Saint Petersburg, Russia) on 13 June 1966, to Jewish parents,[11][12][13] Yakov (who now lives in Israel)[11] and Lyubov (who still lives in Saint Petersburg with Grigori).[11] Grigori's mother Lyubov gave up graduate work in mathematics to raise him. Grigori's mathematical talent became apparent at the age of ten, and his mother enrolled him in Sergei Rukshin's after-school mathematics training program.[14]

His mathematical education continued at the Leningrad Secondary School 239, a specialized school with advanced mathematics and physics programs. Grigori excelled in all subjects except physical education.[15] In 1982, as a member of the Soviet Union team competing in the International Mathematical Olympiad, an international competition for high school students, he won a gold medal, achieving a perfect score.[16] He continued as a student of The School of Mathematics and Mechanics at the Leningrad State University, without admission examinations and enrolled to the university.[16]

After completing his PhD in 1990, Perelman began work at the Leningrad Department of Steklov Institute of Mathematics of the USSR Academy of Sciences, where his advisors were Aleksandr Aleksandrov and Yuri Burago. In the late 1980s and early 1990s, with a strong recommendation from the geometer Mikhail Gromov,[17] Perelman obtained research positions at several universities in the United States. In 1991, Perelman won the Young Mathematician Prize of the St. Petersburg Mathematical Society for his work on Aleksandrov's spaces of curvature bounded from below.[18] In 1992, he was invited to spend a semester each at the Courant Institute in New York University and Stony Brook University where he began work on manifolds with lower bounds on Ricci curvature. From there, he accepted a two-year Miller Research Fellowship at the University of California, Berkeley in 1993. After having proved the soul conjecture in 1994, he was offered jobs at several top universities in the US, including Princeton and Stanford, but he rejected them all and returned to the Steklov Institute in Saint Petersburg in the summer of 1995 for a research-only position.[14]

Early research

Convex geometry

In his undergraduate studies, Perelman dealt with issues in the field of convex geometry. His first published article studied the combinatorial structures arising from intersections of convex polyhedra.[P85] With I. V. Polikanova, he established a measure-theoretic formulation of Helly's theorem.[PP86] In 1987, the year he began graduate studies, he published an article controlling the size of circumscribed cylinders by that of inscribed spheres.[P87]

Negatively curved hypersurfaces

Surfaces of negative curvature were the subject of Perelman's graduate studies. His first result was on the possibility of prescribing the structure of negatively-curved polyhedral surfaces in three-dimensional Euclidean space. He proved that any such metric on the plane which is complete can be continuously immersed as a polyhedral surface.[P88] Later, he constructed an example of a smooth hypersurface of four-dimensional Euclidean space which is complete and has Gaussian curvature negative and bounded away from zero. Previous examples of such surfaces were known, but Perelman's was the first to exhibit the saddle property on nonexistence of locally strictly supporting hyperplanes.[P89] As such, his construction provided further obstruction to the extension of a well-known theorem of Nikolai Efimov to higher dimensions.[19]

Alexandrov spaces

Perelman's first works to a have a major impact on the mathematical literature were in the field of Alexandrov spaces, the concept of which dates back to the 1950s. In a very well-known paper coauthored with Yuri Burago and Mikhael Gromov, Perelman established the modern foundations of this field, with the notion of Gromov–Hausdorff convergence as an organizing principle.[BGP92] In a followup unpublished paper, Perelman proved his "stability theorem," asserting that in the collection of all Alexandrov spaces with a fixed curvature bound, all elements of any sufficiently small metric ball around a compact space are mutually homeomorphic.[P91] Vitali Kapovitch, who described Perelman's article as being "very hard to read," later wrote a detailed version of Perelman's proof, making use of some further simplifications.

Perelman developed a version of Morse theory on Alexandrov spaces.[P93] Despite the lack of smoothness in Alexandrov spaces, Perelman and Anton Petrunin were able to consider the gradient flow of certain functions, in unpublished work.[PP95] They also introduced the notion of an "extremal subset" of Alexandrov spaces, and showed that the interiors of certain extremal subsets define a stratification of the space by topological manifolds.[PP93] In further unpublished work, Perelman studied DC functions (difference of concave functions) on Alexandrov spaces and established that the set of regular points has the structure of a manifold modeled on DC functions.[P95d]

For his work on Alexandrov spaces, Perelman was recognized with an invited lecture at the 1994 International Congress of Mathematicians.[P95a]

Comparison geometry

In 1972, Jeff Cheeger and Detlef Gromoll established their important soul theorem. It asserts that every complete Riemannian metric of nonnegative sectional curvature has a compact nonnegatively curved submanifold, called a soul, whose normal bundle is diffeomorphic to the original space. From the perspective of homotopy theory, this says in particular that every complete Riemannian metric of nonnegative sectional curvature may be taken to be closed. Cheeger and Gromoll conjectured that if the curvature is strictly positive somewhere, then the soul can be taken to be a single point, and hence that the original space must be diffeomorphic to Euclidean space. In 1994, Perelman gave a short proof of Cheeger and Gromoll's conjecture by establishing that, under the condition of nonnegative sectional curvature, Sharafutdinov's retraction is a submersion.[P94b] Perelman's theorem is significant in establishing a topological obstruction to deforming a nonnegatively curved metric to one which is positively curved, even at a single point.

Some of Perelman's work dealt with the construction of various interesting Riemannian manifolds with positive Ricci curvature. He found Riemannian metrics on the connected sum of arbitrarily many complex projective planes with positive Ricci curvature, bounded diameter, and volume bounded away from zero.[P97b] Also, he found an explicit complete metric on four-dimensional Euclidean space with positive Ricci curvature and Euclidean volume growth, and such that the asymptotic cone is nonuniquely defined.[P97c]

Geometrization and Poincaré conjectures

The problems

Main articles: Poincaré conjecture and Thurston's geometrization conjecture

The Poincaré conjecture, proposed by mathematician Henri Poincaré in 1904, was throughout the 20th century regarded as a key problem in topology. On the 3-sphere, defined as the set of points at unit length from the origin in four-dimensional Euclidean space, any loop can be contracted into a point. Poincaré suggested that a converse might be true: if a closed three-dimensional manifold has the property that any loop can be contracted into a point, then it must be topologically equivalent to a 3-sphere. Stephen Smale proved a high-dimensional analogue of Poincaré's conjecture in 1961, and Michael Freedman proved the four-dimensional version in 1982.[20][21] Despite their work, the case of three-dimensional spaces remained completely unresolved. Moreover, Smale and Freedman's methods have had no impact on the three-dimensional case, as their topological manipulations, moving "problematic regions" out of the way without interfering with other regions, seem to require high dimensions in order to work.

In 1982, William Thurston developed a novel viewpoint, making the Poincaré conjecture into a small special case of a hypothetical systematic structure theory of topology in three dimensions. His proposal, known as the Thurston geometrization conjecture, posited that given any closed three-dimensional manifold whatsoever, there is some collection of two-dimensional spheres and tori inside of the manifold which disconnect the space into separate pieces, each of which can be endowed with a uniform geometric structure.[22] Thurston was able to prove his conjecture under some provisional assumptions. In John Morgan's view, it was only with Thurston's systematic viewpoint that most topologists came to believe that the Poincaré conjecture would be true.[23]

At the same time that Thurston published his conjecture, Richard Hamilton introduced his theory of the Ricci flow. Hamilton's Ricci flow is a prescription, defined by a partial differential equation formally analogous to the heat equation, for how to deform a Riemannian metric on a manifold. The heat equation, such as when applied in the sciences to physical phenomena such as temperature, models how concentrations of extreme temperatures will spread out until a uniform temperature is achieved throughout an object. In three seminal articles published in the 1980s, Hamilton proved that his equation achieved analogous phenomena, spreading extreme curvatures and uniformizing a Riemannian metric, in certain geometric settings.[24][25][26] As a byproduct, he was able to prove some new and striking theorems in the field of Riemannian geometry.

Despite formal similarities, Hamilton's equations are significantly more complex and nonlinear than the heat equation, and it is impossible that such uniformization is achieved without contextual assumptions. In completely general settings, it is inevitable that "singularities" occur, meaning that curvature accumulates to infinite levels after a finite amount of "time" has elapsed. Following Shing-Tung Yau's suggestion that a detailed understanding of these singularities could be topologically meaningful, and in particular that their locations might identify the spheres and tori in Thurston's conjecture, Hamilton began a systematic analysis.[27] Throughout the 1990s, he found a number of new technical results and methods,[28] culminating in a 1997 publication constructing a "Ricci flow with surgery" for four-dimensional spaces.[29] As an application of his construction, Hamilton was able to settle a four-dimensional curvature-based analogue of the Poincaré conjecture. Yau has identified this article as one of the most important in the field of geometric analysis, saying that with its publication it became clear that Ricci flow could be powerful enough to settle the Thurston conjecture.[30] The key of Hamilton's analysis was a quantitative understanding of how singularities occur in his four-dimensional setting; the most outstanding difficulty was the quantitative understanding of how singularities occur in three-dimensional settings. Although Hamilton was unable to resolve this issue, in 1999 he published work on Ricci flow in three dimensions, showing that if a three-dimensional version of his surgery techniques could be developed, and if a certain conjecture on the long-time behavior of Ricci flow could be established, then Thurston's conjecture would be resolved.[31] This became known as the Hamilton program.

Perelman's work

In November 2002 and March 2003, Perelman posted two preprints to arXiv, in which he claimed to have outlined a proof of Thurston's conjecture.[P02][P03a] In a third paper posted in July 2003, Perelman outlined an additional argument, sufficient for proving the Poincaré conjecture (but not the Thurston conjecture), the point being to avoid the most technical work in his second preprint.[P03b] Making use of the Almgren-Pitts min-max theory from the field of geometric measure theory, Tobias Colding and William Minicozzi provided a completely alternative proof of the results in Perelman's third preprint.[32][33][34]

Perelman's first preprint contained two primary results, both to do with Ricci flow. The first, valid in any dimension, was based on a novel adaptation of Peter Li and Shing-Tung Yau's differential Harnack inequalities to the setting of Ricci flow.[35] By carrying out the proof of the Bishop-Gromov inequality for the resulting Li−Yau length functional, Perelman established his celebrated "noncollapsing theorem" for Ricci flow, asserting that local control of the size of the curvature implies control of volumes. The significance of the noncollapsing theorem is that volume control is one of the preconditions of Hamilton's compactness theorem. As a consequence, Hamilton's compactness and the corresponding existence of subsequential limits could be applied somewhat freely.

The "canonical neighborhoods theorem" is the second main result of Perelman's first preprint. In this theorem, Perelman achieved the quantitative understanding of singularities of three-dimensional Ricci flow which had eluded Hamilton. Roughly speaking, Perelman showed that on a microscopic level, every singularity looks either like a cylinder collapsing to its axis, or a sphere collapsing to its center. Perelman's proof of his canonical neighborhoods theorem is a highly technical achievement, based upon extensive arguments by contradiction in which Hamilton's compactness theorem (as facilitated by Perelman's noncollapsing theorem) is applied to construct self-contradictory manifolds.

Other results in Perelman's first preprint include the introduction of certain monotonic quantities and a "pseudolocality theorem" which relates curvature control and isoperimetry. However, despite being major results in the theory of Ricci flow, these results were not used in the rest of his work.

The first half of Perelman's second preprint, in addition to fixing some incorrect statements and arguments from the first paper, used his canonical neighborhoods theorem to construct a Ricci flow with surgery in three dimensions, systematically excising singular regions as they develop. As an immediate corollary of his construction, Perelman resolved a major conjecture on the topological classification in three dimensions of closed manifolds which admit metrics of positive scalar curvature. His third preprint (or alternatively Colding and Minicozzi's work) showed that on any space satisfying the assumptions of the Poincaré conjecture, the Ricci flow with surgery exists only for finite time, so that the infinite-time analysis of Ricci flow is irrelevant. The construction of Ricci flow with surgery has the Poincaré conjecture as a corollary.

In order to settle the Thurston conjecture, the second half of Perelman's second preprint is devoted to an analysis of Ricci flows with surgery, which may exist for infinite time. Perelman was unable to resolve Hamilton's 1999 conjecture on long-time behavior, which would make Thurston's conjecture another corollary of the existence of Ricci flow with surgery. Nonetheless, Perelman was able to adapt Hamilton's arguments to the precise conditions of his new Ricci flow with surgery. The end of Hamilton's argument made use of Jeff Cheeger and Mikhael Gromov's theorem characterizing collapsing manifolds. In Perelman's adaptation, he required use of a new theorem characterizing manifolds in which collapsing is only assumed on a local level. In his preprint, he said the proof of his theorem would be established in another paper, but he did not then release any further details. Proofs were later published by Takashi Shioya and Takao Yamaguchi,[36] John Morgan and Gang Tian,[37] Jianguo Cao and Jian Ge,[38] and Bruce Kleiner and John Lott.[39]

Verification

Perelman's preprints quickly gained the attention of the mathematical community, although they were widely seen as hard to understand since they had been written somewhat tersely. Against the usual style in academic mathematical publications, many technical details had been omitted. It was soon apparent that Perelman had made major contributions to the foundations of Ricci flow, although it was not immediately clear to the mathematical community that these contributions were sufficient to prove the geometrization conjecture or the Poincaré conjecture.

In April 2003, Perelman visited the Massachusetts Institute of Technology, Princeton University, Stony Brook University, Columbia University, and New York University to give short series of lectures on his work, and to clarify some details for experts in the relevant fields. In the years afterwards, three detailed expositions appeared, discussed below. Since then, various parts of Perelman's work have also appeared in a number of textbooks and expository articles.

  • In June 2003, Bruce Kleiner and John Lott, both then of the University of Michigan, posted notes on Lott's website which, section by section, filled in details of Perelman's first preprint. In September 2004, their notes were updated to include Perelman's second preprint. Following further revisions and corrections, they posted a version to arXiv on 25 May 2006, a modified version of which was published in the academic journal Geometry & Topology in 2008.[40] At the 2006 International Congress of Mathematicians, Lott said "It has taken us some time to examine Perelman's work. This is partly due to the originality of Perelman's work and partly to the technical sophistication of his arguments. All indications are that his arguments are correct." In the introduction to their article, Kleiner and Lott explained

Perelman's proofs are concise and, at times, sketchy. The purpose of these notes is to provide the details that are missing in [Perelman's first two preprints]... Regarding the proofs, [Perelman's papers] contain some incorrect statements and incomplete arguments, which we have attempted to point out to the reader. (Some of the mistakes in [Perelman's first paper] were corrected in [Perelman's second paper].) We did not find any serious problems, meaning problems that cannot be corrected using the methods introduced by Perelman.

Since its 2008 publication, Kleiner and Lott's article has subsequently been revised twice for corrections, such as for an incorrect statement of Hamilton's important "compactness theorem" for Ricci flow. The latest revision to their article was in 2013.
  • In June 2006, the Asian Journal of Mathematics published an article by Huai-Dong Cao of Lehigh University and Zhu Xiping of Sun Yat-sen University, giving a complete description of Perelman's proof of the Poincaré and the geometrization conjectures. Unlike Kleiner and Lott's article, which was structured as a collection of annotations to Perelman's papers, Cao and Zhu's article was aimed directly towards explaining the proofs of the Poincaré conjecture and geometrization conjecture. In their introduction, they explain

In this paper, we shall present the Hamilton-Perelman theory of Ricci flow. Based on it, we shall give the first written account of a complete proof of the Poincaré conjecture and the geometrization conjecture of Thurston. While the complete work is an accumulated efforts of many geometric analysts, the major contributors are unquestionably Hamilton and Perelman. [...] In this paper, we shall give complete and detailed proofs [...] especially of Perelman's work in his second paper in which many key ideas of the proofs are sketched or outlined but complete details of the proofs are often missing. As we pointed out before, we have to substitute several key arguments of Perelman by new approaches based on our study, because we were unable to comprehend these original arguments of Perelman which are essential to the completion of the geometrization program.

Based also upon the title "A Complete Proof of the Poincaré and Geometrization Conjectures – Application of the Hamilton-Perelman Theory of Ricci Flow" and the phrase "This proof should be considered as the crowning achievement of the Hamilton-Perelman theory of Ricci flow" from the abstract, some people interpreted Cao and Zhu to be taking credit from Perelman for themselves.[41] When asked about the issue, Perelman said that he couldn't see any new contribution by Cao and Zhu and that they "did not quite understand the argument and reworked it."[41] Additionally, one of the pages of Cao and Zhu's article was essentially identical to one from Kleiner and Lott's 2003 posting. In a published erratum,[42] Cao and Zhu attributed this to an oversight, saying that in 2003 they had taken down notes from the initial version of Kleiner and Lott's notes, and in their 2006 writeup had not realized the proper source of the notes. They posted a revised version to arXiv[43] with revisions in their phrasing and in the relevant page of the proof.
  • In July 2006, John Morgan of Columbia University and Gang Tian of the Massachusetts Institute of Technology posted a paper on arXiv in which they provided a detailed presentation of Perelman's proof of the Poincaré conjecture.[44] Unlike Kleiner-Lott and Cao-Zhu's expositions, Morgan and Tian's also deals with Perelman's third paper. On 24 August 2006, Morgan delivered a lecture at the ICM in Madrid on the Poincaré conjecture, in which he declared that Perelman's work had been "thoroughly checked."[45] In 2015, Abbas Bahri pointed out a counterexample to one of Morgan and Tian's theorems, which was later fixed by Morgan and Tian and sourced to an incorrectly computed evolution equation.[46][47] The error, introduced by Morgan and Tian, dealt with details not directly discussed in Perelman's original work. In 2008, Morgan and Tian posted a paper which covered the details of the proof of the geometrization conjecture.[48] Morgan and Tian's two articles have been published in book form by the Clay Mathematics Institute.

Fields Medal and Millennium Prize

In May 2006, a committee of nine mathematicians voted to award Perelman a Fields Medal for his work on the Ricci flow.[41] However, Perelman declined to accept the prize. Sir John Ball, president of the International Mathematical Union, approached Perelman in Saint Petersburg in June 2006 to persuade him to accept the prize. After 10 hours of attempted persuasion over two days, Ball gave up. Two weeks later, Perelman summed up the conversation as follows: "He proposed to me three alternatives: accept and come; accept and don't come, and we will send you the medal later; third, I don't accept the prize. From the very beginning, I told him I have chosen the third one ... [the prize] was completely irrelevant for me. Everybody understood that if the proof is correct, then no other recognition is needed."[41] "'I'm not interested in money or fame,' he is quoted to have said at the time. 'I don't want to be on display like an animal in a zoo. I'm not a hero of mathematics. I'm not even that successful; that is why I don't want to have everybody looking at me.'"[49]

Nevertheless, on 22 August 2006, at the International Congress of Mathematicians in Madrid, Perelman was offered the Fields Medal "for his contributions to geometry and his revolutionary insights into the analytical and geometric structure of the Ricci flow".[50] He did not attend the ceremony and the presenter informed the congress that Perelman declined to accept the medal, which made him the only person to have ever declined the prize.[10][51]

He had previously rejected a prestigious prize from the European Mathematical Society.[10]

On 18 March 2010, Perelman was awarded a Millennium Prize for solving the problem.[52] On 8 June 2010, he did not attend a ceremony in his honor at the Institut Océanographique, Paris to accept his $1 million prize.[53] According to Interfax, Perelman refused to accept the Millennium prize in July 2010. He considered the decision of the Clay Institute unfair for not sharing the prize with Richard S. Hamilton,[8] and stated that "the main reason is my disagreement with the organized mathematical community. I don't like their decisions, I consider them unjust."[9]

The Clay Institute subsequently used Perelman's prize money to fund the "Poincaré Chair", a temporary position for young promising mathematicians at the Paris Institut Henri Poincaré.[54]

Possible withdrawal from mathematics

Perelman quit his job at the Steklov Institute in December 2005.[55] His friends are said to have stated that he currently finds mathematics a painful topic to discuss; by 2010, some even said that he had entirely abandoned mathematics.[56]

Perelman is quoted in a 2006 article in The New Yorker saying that he was disappointed with the ethical standards of the field of mathematics. The article implies that Perelman refers particularly to alleged efforts of Fields medalist Shing-Tung Yau to downplay Perelman's role in the proof and play up the work of Cao and Zhu. Perelman added, "I can't say I'm outraged. Other people do worse. Of course, there are many mathematicians who are more or less honest. But almost all of them are conformists. They are more or less honest, but they tolerate those who are not honest."[41] He also said, "It is not people who break ethical standards who are regarded as aliens. It is people like me who are isolated."[41]

This, combined with the possibility of being awarded a Fields medal, led him to state he had quit professional mathematics by 2006. He said, "As long as I was not conspicuous, I had a choice. Either to make some ugly thing or, if I didn't do this kind of thing, to be treated as a pet. Now, when I become a very conspicuous person, I cannot stay a pet and say nothing. That is why I had to quit." (The New Yorker authors explained Perelman's reference to "some ugly thing" as "a fuss" on Perelman's part about the ethical breaches he perceived.)[57]

It is uncertain whether his resignation from Steklov and subsequent seclusion mean that he has ceased to practice mathematics. Fellow countryman and mathematician Yakov Eliashberg said that, in 2007 Perelman confided to him that he was working on other things but it was too premature to talk about it. He is said to have been interested in the past in the Navier–Stokes equations and the problem of their solutions’ existence and smoothness.[58]

In 2014, Russian media reported that Perelman was working in the field of nanotechnology in Sweden.[59] However, shortly afterwards, he was spotted again in his native hometown, Saint Petersburg.[59]

Perelman and the media

Perelman has avoided journalists and other members of the media. Masha Gessen, author of the mathematician's biography Perfect Rigour: A Genius and the Mathematical Breakthrough of the Century, was unable to meet him.[60]

A Russian documentary about Perelman in which his work is discussed by several leading mathematicians including Mikhail Gromov was released in 2011 under the title "Иноходец. Урок Перельмана" ("Maverick: Perelman's Lesson").

In April 2011, Aleksandr Zabrovsky, producer of "President-Film" studio, claimed to have held an interview with Perelman and agreed to shoot a film about him, under the tentative title The Formula of the Universe.[61] Zabrovsky says that in the interview,[62] Perelman explained why he rejected the one million dollar prize.[61] A number of journalists[63][64][65] believe that Zabrovky's interview is most likely a fake, pointing to contradictions in statements supposedly made by Perelman.

The writer Brett Forrest briefly interacted with Perelman in 2012.[66][67] A reporter who had called him was told: "You are disturbing me. I am picking mushrooms."[68]

Complete publication list

Dissertation

  • Перельман, Григорий Яковлевич (1990). Седловые поверхности в евклидовых пространствах [Saddle surfaces in Euclidean spaces] (in Russian). Ленинградский государственный университет. Автореф. дис. на соиск. учен. степ. канд. физ.-мат. наук.{{cite book}}: CS1 maint: postscript (link)

Research papers

P85.
Perelʹman, G. Ya. (1985). "Realization of abstract k-skeletons as k-skeletons of intersections of convex polyhedra in R2k − 1". In Ivanov, L. D. (ed.). Geometric questions in the theory of functions and sets. Kalinin: Kalinin gosudarstvennyy universitet. pp. 129–131. MR 0829936. Zbl 0621.52003.
PP86.
Polikanova, I. V.; Perelʹman, G. Ya. (1986). "A remark on Helly's theorem". Sibirskij Matematiceskij Zurnal. 27 (5): 191–194. MR 0873724. Zbl 0615.52009.
P87.
Perelʹman, G. Ya. (1987). "k-radii of a convex body". Siberian Mathematical Journal. 28 (4): 665–666. doi:10.1007/BF00973857. MR 0906047. S2CID 122265141. Zbl 0637.52009.
P88.
Perelʹman, G. Ya. (1991). "Polyhedral saddle surfaces". Journal of Soviet Mathematics. 54 (1): 735–740. doi:10.1007/BF01097421. MR 0971977. S2CID 121040191. English translation of Ukrainskiĭ Geometricheskiĭ Sbornik. 31: 100–108. 1988. Zbl 0719.53038. {{cite journal}}: Missing or empty |title= (help)
P89.
Perelʹman, G. Ya. (1992). "An example of a complete saddle surface in R4 with Gaussian curvature bounded away from zero". Journal of Soviet Mathematics. 59 (2): 760–762. doi:10.1007/BF01097177. MR 1049373. S2CID 121011846. English translation of Ukrainskiĭ Geometricheskiĭ Sbornik. 32: 99–102. 1989. Zbl 0741.53037. {{cite journal}}: Missing or empty |title= (help)
BGP92.
Burago, Yu.; Gromov, M.; Perelʹman, G. (1992). "A. D. Aleksandrov spaces with curvatures bounded below". Russian Mathematical Surveys. 47 (2): 1–58. doi:10.1070/RM1992v047n02ABEH000877. MR 1185284. S2CID 250908096. Zbl 0802.53018.
P93.
Perelʹman, G. Ya. (1994). "Elements of Morse theory on Aleksandrov spaces". St. Petersburg Mathematical Journal. 5 (1): 205–213. MR 1220498. English translation of Algebra i Analiz. 5 (1): 232–241. 1993. Zbl 0815.53072. {{cite journal}}: Missing or empty |title= (help)
PP93.
Perelʹman, G. Ya.; Petrunin, A. M. (1994). "Extremal subsets in Aleksandrov spaces and the generalized Liberman theorem". St. Petersburg Mathematical Journal. 5 (1): 215–227. MR 1220499. English translation of Algebra i Analiz. 5 (1): 242–256. 1993. Zbl 0802.53019. {{cite journal}}: Missing or empty |title= (help)
P94a.
Perelman, G. (1994). "Manifolds of positive Ricci curvature with almost maximal volume". Journal of the American Mathematical Society. 7 (2): 299–305. doi:10.1090/S0894-0347-1994-1231690-7. MR 1231690. Zbl 0799.53050.
P94b.
Perelman, G. (1994). "Proof of the soul conjecture of Cheeger and Gromoll". Journal of Differential Geometry. 40 (1): 209–212. doi:10.4310/jdg/1214455292. MR 1285534. S2CID 118147865. Zbl 0818.53056.
P95a.
Perelman, G. (1995). "Spaces with curvature bounded below" (PDF). In Chatterji, S. D. (ed.). Proceedings of the International Congress of Mathematicians, Vol. 1. Zürich, Switzerland ( 3–11 August 1994). Basel: Birkhäuser. pp. 517–525. doi:10.1007/978-3-0348-9078-6. ISBN 3-7643-5153-5. MR 1403952. Zbl 0838.53033.
P95b.
Perelman, G. (1995). "A diameter sphere theorem for manifolds of positive Ricci curvature". Mathematische Zeitschrift. 218 (4): 595–596. doi:10.1007/BF02571925. MR 1326988. S2CID 122333596. Zbl 0831.53033.
P95c.
Perelman, G. (1995). "Widths of nonnegatively curved spaces". Geometric and Functional Analysis. 5 (2): 445–463. doi:10.1007/BF01895675. MR 1334875. S2CID 120415759. Zbl 0845.53031.
P97a.
Perelman, G. (1997). "Collapsing with no proper extremal subsets" (PDF). In Grove, Karsten; Petersen, Peter (eds.). Comparison geometry. Special Year in Differential Geometry held in Berkeley, CA, 1993–94. Mathematical Sciences Research Institute Publications. Vol. 30. Cambridge: Cambridge University Press. pp. 149–155. ISBN 0-521-59222-4. MR 1452871. Zbl 0887.53049.
P97b.
Perelman, G. (1997). "Construction of manifolds of positive Ricci curvature with big volume and large Betti numbers" (PDF). In Grove, Karsten; Petersen, Peter (eds.). Comparison geometry. Special Year in Differential Geometry held in Berkeley, CA, 1993–94. Mathematical Sciences Research Institute Publications. Vol. 30. Cambridge: Cambridge University Press. pp. 157–163. ISBN 0-521-59222-4. MR 1452872. Zbl 0890.53038.
P97c.
Perelman, G. (1997). "A complete Riemannian manifold of positive Ricci curvature with Euclidean volume growth and nonunique asymptotic cone" (PDF). In Grove, Karsten; Petersen, Peter (eds.). Comparison geometry. Special Year in Differential Geometry held in Berkeley, CA, 1993–94. Mathematical Sciences Research Institute Publications. Vol. 30. Cambridge: Cambridge University Press. pp. 165–166. ISBN 0-521-59222-4. MR 1452873. Zbl 0887.53038.

Unpublished work

P91.
Perelman, G. (1991). Alexandrov's spaces with curvatures bounded from below II (PDF) (Preprint).
  • See also: Kapovitch, Vitali (2007). "Perelman's stability theorem". In Cheeger, Jeffrey; Grove, Karsten (eds.). Metric and Comparison Geometry. Surveys in Differential Geometry. Vol. 11. Somerville, MA: International Press. pp. 103–136. doi:10.4310/SDG.2006.v11.n1.a5. ISBN 978-1-57146-117-9. MR 2408265.
PP95.
Perelman, G.; Petrunin, A. (1995). Quasigeodesics and gradient curves in Alexandrov spaces (PDF) (Preprint).
P95d.
Perelman, G. (1995). DC structure on Alexandrov space (preliminary version) (PDF) (Preprint).
P02.
Perelman, Grisha (2002). "The entropy formula for the Ricci flow and its geometric applications". arXiv:math/0211159. Zbl 1130.53001
P03a.
Perelman, Grisha (2003). "Ricci flow with surgery on three-manifolds". arXiv:math/0303109. Zbl 1130.53002
P03b.
Perelman, Grisha (2003). "Finite extinction time for the solutions to the Ricci flow on certain three-manifolds". arXiv:math/0307245. Zbl 1130.53003

See also

Notes

  1. ^ "Perfect Rigour: A Genius and the Mathematical Breakthrough of the Century by Masha Gessen – review". the Guardian. 27 March 2011. Retrieved 25 July 2022.
  2. ^ Company, Sudo Null. "Sudo Null – Latest IT News". SudoNull. Retrieved 25 July 2022.
  3. ^ "Brilliant & Reclusive Russian Mathematician Doesn't Need Your Prize Money". Discover Magazine. Retrieved 25 July 2022.
  4. ^ . International Mathematical Union (IMU) – Prizes. Archived from the original on June 17, 2013. Retrieved April 30, 2006.
  5. ^ "Russian maths genius Perelman urged to take $1m prize". BBC News. 24 March 2010.
  6. ^ Dana Mackenzie (2006). "Breakthrough of the year. The Poincaré Conjecture – Proved". Science. 314 (5807): 1848–1849. doi:10.1126/science.314.5807.1848. PMID 17185565.
  7. ^ . Archived from the original on 5 July 2014. Retrieved 1 May 2014.
  8. ^ a b "Последнее "нет" доктора Перельмана". Interfax. 1 July 2010. from the original on 2 July 2010. Retrieved 1 July 2010.
  9. ^ a b Malcolm Ritter (1 July 2010). "Russian mathematician rejects $1 million prize". AP on PhysOrg. from the original on 17 January 2012. Retrieved 15 May 2011.
  10. ^ a b c "Maths genius declines top prize". BBC News. 22 August 2006. from the original on 15 August 2010.
  11. ^ a b c Osborn, Andrew (27 March 2010). "Russian maths genius may turn down $1m prize". The Daily Telegraph. from the original on 30 March 2010. Retrieved 2 July 2010. He has suffered anti-Semitism (he is Jewish)....Grigory is pure Jewish and I never minded that but my bosses did
  12. ^ McKie, Robin (27 March 2011). "Perfect Rigour: A Genius and the Mathematical Breakthrough of the Century by Masha Gessen – review". The Guardian. from the original on 4 October 2013. Retrieved 23 August 2013. Given that his parents were Jewish, Perelman, who was born in 1966, was fortunate in those who took up his cause.
  13. ^ Gessen (2009, p. 48)
  14. ^ a b John Allen Paulos (29 April 2010). "He Conquered the Conjecture". The New York Review of Books.
  15. ^ "Eccentric 'Mathsputin' Rejects Million Dollar Prize". Fox News. from the original on 15 July 2014. Retrieved 8 July 2014.
  16. ^ a b "International Mathematical Olympiad". Imo-official.org. from the original on 2 November 2012. Retrieved 25 December 2012.
  17. ^ Gessen (2009, p. 45)
  18. ^ "Young mathematician prize of the St. Petersburg Mathematical Society".
  19. ^ Efimov, N. V. Generation of singularites on surfaces of negative curvature. Mat. Sb. (N.S.) 64 (106) 1964 286–320.
  20. ^ Smale, Stephen. Generalized Poincaré's conjecture in dimensions greater than four. Ann. of Math. (2) 74 (1961), 391–406.
  21. ^ Freedman, Michael Hartley. The topology of four-dimensional manifolds. J. Differential Geometry 17 (1982), no. 3, 357–453.
  22. ^ Thurston, William P. Three-dimensional manifolds, Kleinian groups and hyperbolic geometry. Bull. Amer. Math. Soc. (N.S.) 6 (1982), no. 3, 357–381.
  23. ^ John Morgan. "The Poincaré conjecture." Lecture at 2006 International Congress of Mathematicians.
  24. ^ Hamilton, Richard S. Three-manifolds with positive Ricci curvature. J. Differential Geometry 17 (1982), no. 2, 255–306.
  25. ^ Hamilton, Richard S. Four-manifolds with positive curvature operator. J. Differential Geom. 24 (1986), no. 2, 153–179.
  26. ^ Hamilton, Richard S. The Ricci flow on surfaces. Mathematics and general relativity (Santa Cruz, CA, 1986), 237–262, Contemp. Math., 71, Amer. Math. Soc., Providence, RI, 1988.
  27. ^ "Autobiography of Richard S Hamilton | the Shaw Prize".
  28. ^ Hamilton, Richard S. (1995). "The formation of singularities in the Ricci flow". Surveys in Differential Geometry. II: 7–136.
  29. ^ Hamilton, Richard S. (1997). "Four-manifolds with positive isotropic curvature". Comm. Anal. Geom. 5 (1): 1–92. doi:10.4310/CAG.1997.v5.n1.a1.
  30. ^ Yau, Shing-Tung. Perspectives on geometric analysis. Surveys in differential geometry. Vol. X, 275–379, Surv. Differ. Geom., 10, Int. Press, Somerville, MA, 2006.
  31. ^ Hamilton, Richard S. Non-singular solutions of the Ricci flow on three-manifolds. Comm. Anal. Geom. 7 (1999), no. 4, 695–729.
  32. ^ Colding, Tobias H.; Minicozzi, William P., II. Estimates for the extinction time for the Ricci flow on certain 3-manifolds and a question of Perelman. J. Amer. Math. Soc. 18 (2005), no. 3, 561–569.
  33. ^ Colding, Tobias H.; Minicozzi, William P., II. Width and finite extinction time of Ricci flow. Geom. Topol. 12 (2008), no. 5, 2537–2586.
  34. ^ Colding, Tobias Holck; Minicozzi, William P., II. A course in minimal surfaces. Graduate Studies in Mathematics, 121. American Mathematical Society, Providence, RI, 2011. xii+313 pp. ISBN 978-0-8218-5323-8
  35. ^ Li, Peter; Yau, Shing-Tung. On the parabolic kernel of the Schrödinger operator. Acta Math. 156 (1986), no. 3-4, 153–201.
  36. ^ Shioya, Takashi; Yamaguchi, Takao. Volume collapsed three-manifolds with a lower curvature bound. Math. Ann. 333 (2005), no. 1, 131–155.
  37. ^ Morgan, John; Tian, Gang. The geometrization conjecture. Clay Mathematics Monographs, 5. American Mathematical Society, Providence, RI; Clay Mathematics Institute, Cambridge, MA, 2014. x+291 pp. ISBN 978-0-8218-5201-9
  38. ^ Cao, Jianguo; Ge, Jian. A simple proof of Perelman's collapsing theorem for 3-manifolds. J. Geom. Anal. 21 (2011), no. 4, 807–869.
  39. ^ Kleiner, Bruce; Lott, John. Locally collapsed 3-manifolds. Astérisque No. 365 (2014), 7–99. ISBN 978-2-85629-795-7
  40. ^ Kleiner, Bruce; Lott, John (2008). "Notes on Perelman's papers". Geometry & Topology. 12 (5): 2587–2855. arXiv:math/0605667. doi:10.2140/gt.2008.12.2587. S2CID 119133773.
  41. ^ a b c d e f Nasar, Sylvia; Gruber, David (21 August 2006). "Manifold Destiny: A legendary problem and the battle over who solved it". The New Yorker. from the original on 19 March 2011. Retrieved 21 January 2011.
  42. ^ Cao, Huai-Dong; Zhu, Xi-Ping (2006). "Erratum to "A complete proof of the Poincaré and geometrization conjectures – application of the Hamilton–Perelman theory of the Ricci flow", Asian J. Math., Vol. 10, No. 2, 165–492, 2006". Asian Journal of Mathematics. 10 (4): 663–664. doi:10.4310/ajm.2006.v10.n2.a2. MR 2282358.
  43. ^ Cao, Huai-Dong; Zhu, Xi-Ping (3 December 2006). "Hamilton–Perelman's Proof of the Poincaré Conjecture and the Geometrization Conjecture". arXiv:math.DG/0612069.
  44. ^ John W. Morgan, Gang Tian Ricci Flow and the Poincaré Conjecture arXiv:math/0607607
  45. ^ . Icm2006.org. Archived from the original on 11 February 2010. Retrieved 21 March 2010.
  46. ^ Bahri, Abbas (2015). "Five gaps in mathematics". Adv. Nonlinear Stud. 15 (2): 289–319. doi:10.1515/ans-2015-0202. S2CID 125566270.
  47. ^ Morgan, John; Tian, Gang (2015), Correction to Section 19.2 of Ricci Flow and the Poincare Conjecture, arXiv:1512.00699, Bibcode:2015arXiv151200699M.
  48. ^ John W. Morgan, Gang Tian Completion of the Proof of the Geometrization Conjecture arXiv:0809.4040
  49. ^ "Maths genius urged to take prize". BBC News. 24 March 2010. from the original on 19 April 2010. Retrieved 25 March 2010.
  50. ^ (PDF). International Congress of Mathematicians 2006. 22 August 2006. Archived from the original (PDF) on 3 November 2012. Retrieved 22 August 2006.
  51. ^ Mullins, Justin (22 August 2006). "Prestigious Fields Medals for mathematics awarded". New Scientist.
  52. ^ "Prize for Resolution of the Poincaré Conjecture Awarded to Dr. Grigoriy Perelman" (PDF) (Press release). Clay Mathematics Institute. 18 March 2010. Retrieved 1 May 2014. The Clay Mathematics Institute (CMI) announces today that Dr. Grigoriy Perelman of St. Petersburg, Russia, is the recipient of the Millennium Prize for resolution of the Poincaré conjecture.
  53. ^ "Russian math genius ignores $1 million Millennium Prize". RIA Novosti. 8 July 2010. from the original on 11 June 2010. Retrieved 8 July 2010.
  54. ^ "Poincaré Chair". Clay Institute. 4 March 2014.
  55. ^ Gessen (2009, p. 185)
  56. ^ Главные новости (in Russian). RBC Information Systems. 22 August 2006. from the original on 16 July 2011. Retrieved 21 March 2010.
  57. ^ Nasar, Sylvia; Gruber, David (21 August 2006). "Manifold Destiny: A legendary problem and the battle over who solved it". The New Yorker. p. 11. from the original on 18 October 2012. Retrieved 21 January 2011.
  58. ^ "Le génie qui s'est retiré du monde" [The genius who has withdrawn from the world]. Le Point (in French). 30 September 2010. pp. 74–77. from the original on 21 July 2012. Retrieved 15 October 2010.
  59. ^ a b "Komsomolskaya Pravda" found out where Perelman disappears ANNA VELIGZHANINA
  60. ^ Nikolai Gerasimov (27 March 2011). Чтобы купить русского хлеба, Перельман пешком ходил через весь Нью-Йорк [To buy Russian bread, Perelman walked through the whole New York]. Komsomolskaya Pravda (in Russian). from the original on 17 September 2012. Retrieved 25 December 2012.
  61. ^ a b Anna Veligzhanina (28 April 2011). Интервью с математиком Григорием Перельманом: Зачем мне миллион долларов? Я могу управлять Вселенной [Interview with mathematician Grigori Perelman: Why do I need million dollars? I can control the world]. Komsomolskaya Pravda (in Russian). from the original on 27 December 2012. Retrieved 25 December 2012.
  62. ^ "Russian math genius answers $1 million question". RIA Novosti. 29 April 2011. Retrieved 25 December 2012.
  63. ^ Masha Gessen (29 April 2011). "6 странных ошибок в "интервью Перельмана"". Snob.ru. from the original on 17 October 2012. Retrieved 8 May 2012.
  64. ^ "Интервью Перельмана – подделка?" [Interview with Perelman – fake?]. Versii. 5 May 2011. from the original on 26 December 2012. Retrieved 25 December 2012.
  65. ^ "Grigori Perelman's interview full of mismatches". English Pravda.ru. 5 June 2011. from the original on 22 January 2013. Retrieved 25 December 2012.
  66. ^ "Articles » Shattered Genius". Brett Forrest. Retrieved 25 December 2012.
  67. ^ "Seven of the week's best reads". BBC News. 1 September 2012. from the original on 8 March 2013. Retrieved 25 December 2012.
  68. ^ Luke Harding (23 March 2010). "Grigory Perelman, the maths genius who said no to $1m". The Guardian.

References

  • Anderson, M.T. 2005. Singularities of the Ricci flow. Encyclopedia of Mathematical Physics, Elsevier.
  • The Associated Press, "Russian may have solved great math mystery". CNN. 1 July 2004. from the original on 13 August 2006. Retrieved 15 August 2006.
  • Cao, Huai-Dong; Zhu, Xi-Ping (June 2006). (PDF). Asian Journal of Mathematics. 10 (2). Archived from the original (PDF) on 14 May 2012. . Revised version (December 2006): Hamilton-Perelman's Proof of the Poincaré Conjecture and the Geometrization Conjecture
  • Collins, Graham P. (2004). "The Shapes of Space". Scientific American. 291 (July): 94–103. Bibcode:2004SciAm.291a..94C. doi:10.1038/scientificamerican0704-94. PMID 15255593.
  • Gessen, Masha (2009). Perfect Rigor: A Genius and the Mathematical Breakthrough of the Century. Boston, Massachusetts: Houghton Mifflin Harcourt. ISBN 978-0151014064.
  • Jackson, Allyn (September 2006). "Conjectures No More? Consensus Forming on the Proof of the Poincaré and Geometrization Conjectures" (PDF). Notices of the AMS.
  • Kleiner, Bruce; Lott, John (2008). "Notes on Perelman's papers". Geometry & Topology. 12 (5): 2587–2855. arXiv:math.DG/0605667. doi:10.2140/gt.2008.12.2587. S2CID 119133773.
  • Kusner, Rob. "Witnesses to Mathematical History Ricci Flow and Geometry" (PDF). Retrieved 22 August 2006. (an account of Perelman's talk on his proof at MIT; pdf file; also see Sugaku Seminar 2003–10 pp 4–7 for an extended version in Japanese)
  • Morgan, John W.; Gang Tian (25 July 2006). "Ricci Flow and the Poincaré Conjecture". arXiv:math.DG/0607607.

External links

  Media related to Grigori Perelman at Wikimedia Commons

January 26, 2023
grigori, perelman, this, name, that, follows, eastern, slavic, naming, conventions, patronymic, yakovlevich, family, name, perelman, grigori, yakovlevich, perelman, russian, Григорий, Яковлевич, Перельман, ɡrʲɪˈɡorʲɪj, ˈjakəvlʲɪvʲɪtɕ, pʲɪrʲɪlʲˈman, listen, bor. In this name that follows Eastern Slavic naming conventions the patronymic is Yakovlevich and the family name is Perelman Grigori Yakovlevich Perelman Russian Grigorij Yakovlevich Perelman IPA ɡrʲɪˈɡorʲɪj ˈjakevlʲɪvʲɪtɕ pʲɪrʲɪlʲˈman listen born 13 June 1966 is a Russian mathematician who is known for his contributions to the fields of geometric analysis Riemannian geometry and geometric topology He is widely regarded as one of the greatest living mathematicians 1 2 3 Grigori PerelmanGrigori Perelman in 1993Born 1966 06 13 13 June 1966 age 56 Leningrad Soviet UnionNationalityRussianCitizenshipRussiaAlma materLeningrad State University PhD Known forProof of the soul conjecture Proof of the Poincare conjecture and geometrization of 3 manifoldsAwardsSaint Petersburg Mathematical Society Prize 1991 EMS Prize 1996 declined Fields Medal 2006 declined Millennium Prize 2010 declinedScientific careerFieldsDifferential geometryGeometric analysisGeometric topologyThesisSaddle Surfaces in Euclidean Spaces 1990 Doctoral advisorAleksandr Aleksandrov Yuri BuragoIn the 1990s partly in collaboration with Yuri Burago Mikhael Gromov and Anton Petrunin he made contributions to the study of Alexandrov spaces In 1994 he proved the soul conjecture in Riemannian geometry which had been an open problem for the previous 20 years In 2002 and 2003 he developed new techniques in the analysis of Ricci flow and proved the Poincare conjecture and Thurston s geometrization conjecture the former of which had been a famous open problem in mathematics for the past century The full details of Perelman s work were filled in and explained by various authors over the following several years In August 2006 Perelman was offered the Fields Medal 4 for his contributions to geometry and his revolutionary insights into the analytical and geometric structure of the Ricci flow but he declined the award stating I m not interested in money or fame I don t want to be on display like an animal in a zoo 5 On 22 December 2006 the scientific journal Science recognized Perelman s proof of the Poincare conjecture as the scientific Breakthrough of the Year the first such recognition in the area of mathematics 6 On 18 March 2010 it was announced that he had met the criteria to receive the first Clay Millennium Prize 7 for resolution of the Poincare conjecture On 1 July 2010 he rejected the prize of one million dollars saying that he considered the decision of the board of the Clay Institute to be unfair in that his contribution to solving the Poincare conjecture was no greater than that of Richard S Hamilton the mathematician who pioneered the Ricci flow partly with the aim of attacking the conjecture 8 9 He had previously rejected the prestigious prize of the European Mathematical Society in 1996 10 Contents 1 Early life and education 2 Early research 2 1 Convex geometry 2 2 Negatively curved hypersurfaces 2 3 Alexandrov spaces 2 4 Comparison geometry 3 Geometrization and Poincare conjectures 3 1 The problems 3 2 Perelman s work 3 3 Verification 4 Fields Medal and Millennium Prize 5 Possible withdrawal from mathematics 6 Perelman and the media 7 Complete publication list 8 See also 9 Notes 10 References 11 External linksEarly life and education EditGrigori Yakovlevich Perelman was born in Leningrad Soviet Union now Saint Petersburg Russia on 13 June 1966 to Jewish parents 11 12 13 Yakov who now lives in Israel 11 and Lyubov who still lives in Saint Petersburg with Grigori 11 Grigori s mother Lyubov gave up graduate work in mathematics to raise him Grigori s mathematical talent became apparent at the age of ten and his mother enrolled him in Sergei Rukshin s after school mathematics training program 14 His mathematical education continued at the Leningrad Secondary School 239 a specialized school with advanced mathematics and physics programs Grigori excelled in all subjects except physical education 15 In 1982 as a member of the Soviet Union team competing in the International Mathematical Olympiad an international competition for high school students he won a gold medal achieving a perfect score 16 He continued as a student of The School of Mathematics and Mechanics at the Leningrad State University without admission examinations and enrolled to the university 16 After completing his PhD in 1990 Perelman began work at the Leningrad Department of Steklov Institute of Mathematics of the USSR Academy of Sciences where his advisors were Aleksandr Aleksandrov and Yuri Burago In the late 1980s and early 1990s with a strong recommendation from the geometer Mikhail Gromov 17 Perelman obtained research positions at several universities in the United States In 1991 Perelman won the Young Mathematician Prize of the St Petersburg Mathematical Society for his work on Aleksandrov s spaces of curvature bounded from below 18 In 1992 he was invited to spend a semester each at the Courant Institute in New York University and Stony Brook University where he began work on manifolds with lower bounds on Ricci curvature From there he accepted a two year Miller Research Fellowship at the University of California Berkeley in 1993 After having proved the soul conjecture in 1994 he was offered jobs at several top universities in the US including Princeton and Stanford but he rejected them all and returned to the Steklov Institute in Saint Petersburg in the summer of 1995 for a research only position 14 Early research EditConvex geometry Edit In his undergraduate studies Perelman dealt with issues in the field of convex geometry His first published article studied the combinatorial structures arising from intersections of convex polyhedra P85 With I V Polikanova he established a measure theoretic formulation of Helly s theorem PP86 In 1987 the year he began graduate studies he published an article controlling the size of circumscribed cylinders by that of inscribed spheres P87 Negatively curved hypersurfaces Edit Surfaces of negative curvature were the subject of Perelman s graduate studies His first result was on the possibility of prescribing the structure of negatively curved polyhedral surfaces in three dimensional Euclidean space He proved that any such metric on the plane which is complete can be continuously immersed as a polyhedral surface P88 Later he constructed an example of a smooth hypersurface of four dimensional Euclidean space which is complete and has Gaussian curvature negative and bounded away from zero Previous examples of such surfaces were known but Perelman s was the first to exhibit the saddle property on nonexistence of locally strictly supporting hyperplanes P89 As such his construction provided further obstruction to the extension of a well known theorem of Nikolai Efimov to higher dimensions 19 Alexandrov spaces Edit Perelman s first works to a have a major impact on the mathematical literature were in the field of Alexandrov spaces the concept of which dates back to the 1950s In a very well known paper coauthored with Yuri Burago and Mikhael Gromov Perelman established the modern foundations of this field with the notion of Gromov Hausdorff convergence as an organizing principle BGP92 In a followup unpublished paper Perelman proved his stability theorem asserting that in the collection of all Alexandrov spaces with a fixed curvature bound all elements of any sufficiently small metric ball around a compact space are mutually homeomorphic P91 Vitali Kapovitch who described Perelman s article as being very hard to read later wrote a detailed version of Perelman s proof making use of some further simplifications Perelman developed a version of Morse theory on Alexandrov spaces P93 Despite the lack of smoothness in Alexandrov spaces Perelman and Anton Petrunin were able to consider the gradient flow of certain functions in unpublished work PP95 They also introduced the notion of an extremal subset of Alexandrov spaces and showed that the interiors of certain extremal subsets define a stratification of the space by topological manifolds PP93 In further unpublished work Perelman studied DC functions difference of concave functions on Alexandrov spaces and established that the set of regular points has the structure of a manifold modeled on DC functions P95d For his work on Alexandrov spaces Perelman was recognized with an invited lecture at the 1994 International Congress of Mathematicians P95a Comparison geometry Edit In 1972 Jeff Cheeger and Detlef Gromoll established their important soul theorem It asserts that every complete Riemannian metric of nonnegative sectional curvature has a compact nonnegatively curved submanifold called a soul whose normal bundle is diffeomorphic to the original space From the perspective of homotopy theory this says in particular that every complete Riemannian metric of nonnegative sectional curvature may be taken to be closed Cheeger and Gromoll conjectured that if the curvature is strictly positive somewhere then the soul can be taken to be a single point and hence that the original space must be diffeomorphic to Euclidean space In 1994 Perelman gave a short proof of Cheeger and Gromoll s conjecture by establishing that under the condition of nonnegative sectional curvature Sharafutdinov s retraction is a submersion P94b Perelman s theorem is significant in establishing a topological obstruction to deforming a nonnegatively curved metric to one which is positively curved even at a single point Some of Perelman s work dealt with the construction of various interesting Riemannian manifolds with positive Ricci curvature He found Riemannian metrics on the connected sum of arbitrarily many complex projective planes with positive Ricci curvature bounded diameter and volume bounded away from zero P97b Also he found an explicit complete metric on four dimensional Euclidean space with positive Ricci curvature and Euclidean volume growth and such that the asymptotic cone is nonuniquely defined P97c Geometrization and Poincare conjectures EditThe problems Edit Main articles Poincare conjecture and Thurston s geometrization conjecture The Poincare conjecture proposed by mathematician Henri Poincare in 1904 was throughout the 20th century regarded as a key problem in topology On the 3 sphere defined as the set of points at unit length from the origin in four dimensional Euclidean space any loop can be contracted into a point Poincare suggested that a converse might be true if a closed three dimensional manifold has the property that any loop can be contracted into a point then it must be topologically equivalent to a 3 sphere Stephen Smale proved a high dimensional analogue of Poincare s conjecture in 1961 and Michael Freedman proved the four dimensional version in 1982 20 21 Despite their work the case of three dimensional spaces remained completely unresolved Moreover Smale and Freedman s methods have had no impact on the three dimensional case as their topological manipulations moving problematic regions out of the way without interfering with other regions seem to require high dimensions in order to work In 1982 William Thurston developed a novel viewpoint making the Poincare conjecture into a small special case of a hypothetical systematic structure theory of topology in three dimensions His proposal known as the Thurston geometrization conjecture posited that given any closed three dimensional manifold whatsoever there is some collection of two dimensional spheres and tori inside of the manifold which disconnect the space into separate pieces each of which can be endowed with a uniform geometric structure 22 Thurston was able to prove his conjecture under some provisional assumptions In John Morgan s view it was only with Thurston s systematic viewpoint that most topologists came to believe that the Poincare conjecture would be true 23 At the same time that Thurston published his conjecture Richard Hamilton introduced his theory of the Ricci flow Hamilton s Ricci flow is a prescription defined by a partial differential equation formally analogous to the heat equation for how to deform a Riemannian metric on a manifold The heat equation such as when applied in the sciences to physical phenomena such as temperature models how concentrations of extreme temperatures will spread out until a uniform temperature is achieved throughout an object In three seminal articles published in the 1980s Hamilton proved that his equation achieved analogous phenomena spreading extreme curvatures and uniformizing a Riemannian metric in certain geometric settings 24 25 26 As a byproduct he was able to prove some new and striking theorems in the field of Riemannian geometry Despite formal similarities Hamilton s equations are significantly more complex and nonlinear than the heat equation and it is impossible that such uniformization is achieved without contextual assumptions In completely general settings it is inevitable that singularities occur meaning that curvature accumulates to infinite levels after a finite amount of time has elapsed Following Shing Tung Yau s suggestion that a detailed understanding of these singularities could be topologically meaningful and in particular that their locations might identify the spheres and tori in Thurston s conjecture Hamilton began a systematic analysis 27 Throughout the 1990s he found a number of new technical results and methods 28 culminating in a 1997 publication constructing a Ricci flow with surgery for four dimensional spaces 29 As an application of his construction Hamilton was able to settle a four dimensional curvature based analogue of the Poincare conjecture Yau has identified this article as one of the most important in the field of geometric analysis saying that with its publication it became clear that Ricci flow could be powerful enough to settle the Thurston conjecture 30 The key of Hamilton s analysis was a quantitative understanding of how singularities occur in his four dimensional setting the most outstanding difficulty was the quantitative understanding of how singularities occur in three dimensional settings Although Hamilton was unable to resolve this issue in 1999 he published work on Ricci flow in three dimensions showing that if a three dimensional version of his surgery techniques could be developed and if a certain conjecture on the long time behavior of Ricci flow could be established then Thurston s conjecture would be resolved 31 This became known as the Hamilton program Perelman s work Edit In November 2002 and March 2003 Perelman posted two preprints to arXiv in which he claimed to have outlined a proof of Thurston s conjecture P02 P03a In a third paper posted in July 2003 Perelman outlined an additional argument sufficient for proving the Poincare conjecture but not the Thurston conjecture the point being to avoid the most technical work in his second preprint P03b Making use of the Almgren Pitts min max theory from the field of geometric measure theory Tobias Colding and William Minicozzi provided a completely alternative proof of the results in Perelman s third preprint 32 33 34 Perelman s first preprint contained two primary results both to do with Ricci flow The first valid in any dimension was based on a novel adaptation of Peter Li and Shing Tung Yau s differential Harnack inequalities to the setting of Ricci flow 35 By carrying out the proof of the Bishop Gromov inequality for the resulting Li Yau length functional Perelman established his celebrated noncollapsing theorem for Ricci flow asserting that local control of the size of the curvature implies control of volumes The significance of the noncollapsing theorem is that volume control is one of the preconditions of Hamilton s compactness theorem As a consequence Hamilton s compactness and the corresponding existence of subsequential limits could be applied somewhat freely The canonical neighborhoods theorem is the second main result of Perelman s first preprint In this theorem Perelman achieved the quantitative understanding of singularities of three dimensional Ricci flow which had eluded Hamilton Roughly speaking Perelman showed that on a microscopic level every singularity looks either like a cylinder collapsing to its axis or a sphere collapsing to its center Perelman s proof of his canonical neighborhoods theorem is a highly technical achievement based upon extensive arguments by contradiction in which Hamilton s compactness theorem as facilitated by Perelman s noncollapsing theorem is applied to construct self contradictory manifolds Other results in Perelman s first preprint include the introduction of certain monotonic quantities and a pseudolocality theorem which relates curvature control and isoperimetry However despite being major results in the theory of Ricci flow these results were not used in the rest of his work The first half of Perelman s second preprint in addition to fixing some incorrect statements and arguments from the first paper used his canonical neighborhoods theorem to construct a Ricci flow with surgery in three dimensions systematically excising singular regions as they develop As an immediate corollary of his construction Perelman resolved a major conjecture on the topological classification in three dimensions of closed manifolds which admit metrics of positive scalar curvature His third preprint or alternatively Colding and Minicozzi s work showed that on any space satisfying the assumptions of the Poincare conjecture the Ricci flow with surgery exists only for finite time so that the infinite time analysis of Ricci flow is irrelevant The construction of Ricci flow with surgery has the Poincare conjecture as a corollary In order to settle the Thurston conjecture the second half of Perelman s second preprint is devoted to an analysis of Ricci flows with surgery which may exist for infinite time Perelman was unable to resolve Hamilton s 1999 conjecture on long time behavior which would make Thurston s conjecture another corollary of the existence of Ricci flow with surgery Nonetheless Perelman was able to adapt Hamilton s arguments to the precise conditions of his new Ricci flow with surgery The end of Hamilton s argument made use of Jeff Cheeger and Mikhael Gromov s theorem characterizing collapsing manifolds In Perelman s adaptation he required use of a new theorem characterizing manifolds in which collapsing is only assumed on a local level In his preprint he said the proof of his theorem would be established in another paper but he did not then release any further details Proofs were later published by Takashi Shioya and Takao Yamaguchi 36 John Morgan and Gang Tian 37 Jianguo Cao and Jian Ge 38 and Bruce Kleiner and John Lott 39 Verification Edit Perelman s preprints quickly gained the attention of the mathematical community although they were widely seen as hard to understand since they had been written somewhat tersely Against the usual style in academic mathematical publications many technical details had been omitted It was soon apparent that Perelman had made major contributions to the foundations of Ricci flow although it was not immediately clear to the mathematical community that these contributions were sufficient to prove the geometrization conjecture or the Poincare conjecture In April 2003 Perelman visited the Massachusetts Institute of Technology Princeton University Stony Brook University Columbia University and New York University to give short series of lectures on his work and to clarify some details for experts in the relevant fields In the years afterwards three detailed expositions appeared discussed below Since then various parts of Perelman s work have also appeared in a number of textbooks and expository articles In June 2003 Bruce Kleiner and John Lott both then of the University of Michigan posted notes on Lott s website which section by section filled in details of Perelman s first preprint In September 2004 their notes were updated to include Perelman s second preprint Following further revisions and corrections they posted a version to arXiv on 25 May 2006 a modified version of which was published in the academic journal Geometry amp Topology in 2008 40 At the 2006 International Congress of Mathematicians Lott said It has taken us some time to examine Perelman s work This is partly due to the originality of Perelman s work and partly to the technical sophistication of his arguments All indications are that his arguments are correct In the introduction to their article Kleiner and Lott explainedPerelman s proofs are concise and at times sketchy The purpose of these notes is to provide the details that are missing in Perelman s first two preprints Regarding the proofs Perelman s papers contain some incorrect statements and incomplete arguments which we have attempted to point out to the reader Some of the mistakes in Perelman s first paper were corrected in Perelman s second paper We did not find any serious problems meaning problems that cannot be corrected using the methods introduced by Perelman Since its 2008 publication Kleiner and Lott s article has subsequently been revised twice for corrections such as for an incorrect statement of Hamilton s important compactness theorem for Ricci flow The latest revision to their article was in 2013 In June 2006 the Asian Journal of Mathematics published an article by Huai Dong Cao of Lehigh University and Zhu Xiping of Sun Yat sen University giving a complete description of Perelman s proof of the Poincare and the geometrization conjectures Unlike Kleiner and Lott s article which was structured as a collection of annotations to Perelman s papers Cao and Zhu s article was aimed directly towards explaining the proofs of the Poincare conjecture and geometrization conjecture In their introduction they explainIn this paper we shall present the Hamilton Perelman theory of Ricci flow Based on it we shall give the first written account of a complete proof of the Poincare conjecture and the geometrization conjecture of Thurston While the complete work is an accumulated efforts of many geometric analysts the major contributors are unquestionably Hamilton and Perelman In this paper we shall give complete and detailed proofs especially of Perelman s work in his second paper in which many key ideas of the proofs are sketched or outlined but complete details of the proofs are often missing As we pointed out before we have to substitute several key arguments of Perelman by new approaches based on our study because we were unable to comprehend these original arguments of Perelman which are essential to the completion of the geometrization program Based also upon the title A Complete Proof of the Poincare and Geometrization Conjectures Application of the Hamilton Perelman Theory of Ricci Flow and the phrase This proof should be considered as the crowning achievement of the Hamilton Perelman theory of Ricci flow from the abstract some people interpreted Cao and Zhu to be taking credit from Perelman for themselves 41 When asked about the issue Perelman said that he couldn t see any new contribution by Cao and Zhu and that they did not quite understand the argument and reworked it 41 Additionally one of the pages of Cao and Zhu s article was essentially identical to one from Kleiner and Lott s 2003 posting In a published erratum 42 Cao and Zhu attributed this to an oversight saying that in 2003 they had taken down notes from the initial version of Kleiner and Lott s notes and in their 2006 writeup had not realized the proper source of the notes They posted a revised version to arXiv 43 with revisions in their phrasing and in the relevant page of the proof In July 2006 John Morgan of Columbia University and Gang Tian of the Massachusetts Institute of Technology posted a paper on arXiv in which they provided a detailed presentation of Perelman s proof of the Poincare conjecture 44 Unlike Kleiner Lott and Cao Zhu s expositions Morgan and Tian s also deals with Perelman s third paper On 24 August 2006 Morgan delivered a lecture at the ICM in Madrid on the Poincare conjecture in which he declared that Perelman s work had been thoroughly checked 45 In 2015 Abbas Bahri pointed out a counterexample to one of Morgan and Tian s theorems which was later fixed by Morgan and Tian and sourced to an incorrectly computed evolution equation 46 47 The error introduced by Morgan and Tian dealt with details not directly discussed in Perelman s original work In 2008 Morgan and Tian posted a paper which covered the details of the proof of the geometrization conjecture 48 Morgan and Tian s two articles have been published in book form by the Clay Mathematics Institute Fields Medal and Millennium Prize EditIn May 2006 a committee of nine mathematicians voted to award Perelman a Fields Medal for his work on the Ricci flow 41 However Perelman declined to accept the prize Sir John Ball president of the International Mathematical Union approached Perelman in Saint Petersburg in June 2006 to persuade him to accept the prize After 10 hours of attempted persuasion over two days Ball gave up Two weeks later Perelman summed up the conversation as follows He proposed to me three alternatives accept and come accept and don t come and we will send you the medal later third I don t accept the prize From the very beginning I told him I have chosen the third one the prize was completely irrelevant for me Everybody understood that if the proof is correct then no other recognition is needed 41 I m not interested in money or fame he is quoted to have said at the time I don t want to be on display like an animal in a zoo I m not a hero of mathematics I m not even that successful that is why I don t want to have everybody looking at me 49 Nevertheless on 22 August 2006 at the International Congress of Mathematicians in Madrid Perelman was offered the Fields Medal for his contributions to geometry and his revolutionary insights into the analytical and geometric structure of the Ricci flow 50 He did not attend the ceremony and the presenter informed the congress that Perelman declined to accept the medal which made him the only person to have ever declined the prize 10 51 He had previously rejected a prestigious prize from the European Mathematical Society 10 On 18 March 2010 Perelman was awarded a Millennium Prize for solving the problem 52 On 8 June 2010 he did not attend a ceremony in his honor at the Institut Oceanographique Paris to accept his 1 million prize 53 According to Interfax Perelman refused to accept the Millennium prize in July 2010 He considered the decision of the Clay Institute unfair for not sharing the prize with Richard S Hamilton 8 and stated that the main reason is my disagreement with the organized mathematical community I don t like their decisions I consider them unjust 9 The Clay Institute subsequently used Perelman s prize money to fund the Poincare Chair a temporary position for young promising mathematicians at the Paris Institut Henri Poincare 54 Possible withdrawal from mathematics EditPerelman quit his job at the Steklov Institute in December 2005 55 His friends are said to have stated that he currently finds mathematics a painful topic to discuss by 2010 some even said that he had entirely abandoned mathematics 56 Perelman is quoted in a 2006 article in The New Yorker saying that he was disappointed with the ethical standards of the field of mathematics The article implies that Perelman refers particularly to alleged efforts of Fields medalist Shing Tung Yau to downplay Perelman s role in the proof and play up the work of Cao and Zhu Perelman added I can t say I m outraged Other people do worse Of course there are many mathematicians who are more or less honest But almost all of them are conformists They are more or less honest but they tolerate those who are not honest 41 He also said It is not people who break ethical standards who are regarded as aliens It is people like me who are isolated 41 This combined with the possibility of being awarded a Fields medal led him to state he had quit professional mathematics by 2006 He said As long as I was not conspicuous I had a choice Either to make some ugly thing or if I didn t do this kind of thing to be treated as a pet Now when I become a very conspicuous person I cannot stay a pet and say nothing That is why I had to quit The New Yorker authors explained Perelman s reference to some ugly thing as a fuss on Perelman s part about the ethical breaches he perceived 57 It is uncertain whether his resignation from Steklov and subsequent seclusion mean that he has ceased to practice mathematics Fellow countryman and mathematician Yakov Eliashberg said that in 2007 Perelman confided to him that he was working on other things but it was too premature to talk about it He is said to have been interested in the past in the Navier Stokes equations and the problem of their solutions existence and smoothness 58 In 2014 Russian media reported that Perelman was working in the field of nanotechnology in Sweden 59 However shortly afterwards he was spotted again in his native hometown Saint Petersburg 59 Perelman and the media EditPerelman has avoided journalists and other members of the media Masha Gessen author of the mathematician s biography Perfect Rigour A Genius and the Mathematical Breakthrough of the Century was unable to meet him 60 A Russian documentary about Perelman in which his work is discussed by several leading mathematicians including Mikhail Gromov was released in 2011 under the title Inohodec Urok Perelmana Maverick Perelman s Lesson In April 2011 Aleksandr Zabrovsky producer of President Film studio claimed to have held an interview with Perelman and agreed to shoot a film about him under the tentative title The Formula of the Universe 61 Zabrovsky says that in the interview 62 Perelman explained why he rejected the one million dollar prize 61 A number of journalists 63 64 65 believe that Zabrovky s interview is most likely a fake pointing to contradictions in statements supposedly made by Perelman The writer Brett Forrest briefly interacted with Perelman in 2012 66 67 A reporter who had called him was told You are disturbing me I am picking mushrooms 68 Complete publication list EditDissertation Perelman Grigorij Yakovlevich 1990 Sedlovye poverhnosti v evklidovyh prostranstvah Saddle surfaces in Euclidean spaces in Russian Leningradskij gosudarstvennyj universitet Avtoref dis na soisk uchen step kand fiz mat nauk a href Template Cite book html title Template Cite book cite book a CS1 maint postscript link Research papers P85 Perelʹman G Ya 1985 Realization of abstract k skeletons as k skeletons of intersections of convex polyhedra in R2k 1 In Ivanov L D ed Geometric questions in the theory of functions and sets Kalinin Kalinin gosudarstvennyy universitet pp 129 131 MR 0829936 Zbl 0621 52003 PP86 Polikanova I V Perelʹman G Ya 1986 A remark on Helly s theorem Sibirskij Matematiceskij Zurnal 27 5 191 194 MR 0873724 Zbl 0615 52009 P87 Perelʹman G Ya 1987 k radii of a convex body Siberian Mathematical Journal 28 4 665 666 doi 10 1007 BF00973857 MR 0906047 S2CID 122265141 Zbl 0637 52009 P88 Perelʹman G Ya 1991 Polyhedral saddle surfaces Journal of Soviet Mathematics 54 1 735 740 doi 10 1007 BF01097421 MR 0971977 S2CID 121040191 English translation of Ukrainskiĭ Geometricheskiĭ Sbornik 31 100 108 1988 Zbl 0719 53038 a href Template Cite journal html title Template Cite journal cite journal a Missing or empty title help P89 Perelʹman G Ya 1992 An example of a complete saddle surface in R4 with Gaussian curvature bounded away from zero Journal of Soviet Mathematics 59 2 760 762 doi 10 1007 BF01097177 MR 1049373 S2CID 121011846 English translation of Ukrainskiĭ Geometricheskiĭ Sbornik 32 99 102 1989 Zbl 0741 53037 a href Template Cite journal html title Template Cite journal cite journal a Missing or empty title help BGP92 Burago Yu Gromov M Perelʹman G 1992 A D Aleksandrov spaces with curvatures bounded below Russian Mathematical Surveys 47 2 1 58 doi 10 1070 RM1992v047n02ABEH000877 MR 1185284 S2CID 250908096 Zbl 0802 53018 P93 Perelʹman G Ya 1994 Elements of Morse theory on Aleksandrov spaces St Petersburg Mathematical Journal 5 1 205 213 MR 1220498 English translation of Algebra i Analiz 5 1 232 241 1993 Zbl 0815 53072 a href Template Cite journal html title Template Cite journal cite journal a Missing or empty title help PP93 Perelʹman G Ya Petrunin A M 1994 Extremal subsets in Aleksandrov spaces and the generalized Liberman theorem St Petersburg Mathematical Journal 5 1 215 227 MR 1220499 English translation of Algebra i Analiz 5 1 242 256 1993 Zbl 0802 53019 a href Template Cite journal html title Template Cite journal cite journal a Missing or empty title help P94a Perelman G 1994 Manifolds of positive Ricci curvature with almost maximal volume Journal of the American Mathematical Society 7 2 299 305 doi 10 1090 S0894 0347 1994 1231690 7 MR 1231690 Zbl 0799 53050 P94b Perelman G 1994 Proof of the soul conjecture of Cheeger and Gromoll Journal of Differential Geometry 40 1 209 212 doi 10 4310 jdg 1214455292 MR 1285534 S2CID 118147865 Zbl 0818 53056 P95a Perelman G 1995 Spaces with curvature bounded below PDF In Chatterji S D ed Proceedings of the International Congress of Mathematicians Vol 1 Zurich Switzerland 3 11 August 1994 Basel Birkhauser pp 517 525 doi 10 1007 978 3 0348 9078 6 ISBN 3 7643 5153 5 MR 1403952 Zbl 0838 53033 P95b Perelman G 1995 A diameter sphere theorem for manifolds of positive Ricci curvature Mathematische Zeitschrift 218 4 595 596 doi 10 1007 BF02571925 MR 1326988 S2CID 122333596 Zbl 0831 53033 P95c Perelman G 1995 Widths of nonnegatively curved spaces Geometric and Functional Analysis 5 2 445 463 doi 10 1007 BF01895675 MR 1334875 S2CID 120415759 Zbl 0845 53031 P97a Perelman G 1997 Collapsing with no proper extremal subsets PDF In Grove Karsten Petersen Peter eds Comparison geometry Special Year in Differential Geometry held in Berkeley CA 1993 94 Mathematical Sciences Research Institute Publications Vol 30 Cambridge Cambridge University Press pp 149 155 ISBN 0 521 59222 4 MR 1452871 Zbl 0887 53049 P97b Perelman G 1997 Construction of manifolds of positive Ricci curvature with big volume and large Betti numbers PDF In Grove Karsten Petersen Peter eds Comparison geometry Special Year in Differential Geometry held in Berkeley CA 1993 94 Mathematical Sciences Research Institute Publications Vol 30 Cambridge Cambridge University Press pp 157 163 ISBN 0 521 59222 4 MR 1452872 Zbl 0890 53038 P97c Perelman G 1997 A complete Riemannian manifold of positive Ricci curvature with Euclidean volume growth and nonunique asymptotic cone PDF In Grove Karsten Petersen Peter eds Comparison geometry Special Year in Differential Geometry held in Berkeley CA 1993 94 Mathematical Sciences Research Institute Publications Vol 30 Cambridge Cambridge University Press pp 165 166 ISBN 0 521 59222 4 MR 1452873 Zbl 0887 53038 Unpublished work P91 Perelman G 1991 Alexandrov s spaces with curvatures bounded from below II PDF Preprint See also Kapovitch Vitali 2007 Perelman s stability theorem In Cheeger Jeffrey Grove Karsten eds Metric and Comparison Geometry Surveys in Differential Geometry Vol 11 Somerville MA International Press pp 103 136 doi 10 4310 SDG 2006 v11 n1 a5 ISBN 978 1 57146 117 9 MR 2408265 PP95 Perelman G Petrunin A 1995 Quasigeodesics and gradient curves in Alexandrov spaces PDF Preprint P95d Perelman G 1995 DC structure on Alexandrov space preliminary version PDF Preprint P02 Perelman Grisha 2002 The entropy formula for the Ricci flow and its geometric applications arXiv math 0211159 Zbl 1130 53001 P03a Perelman Grisha 2003 Ricci flow with surgery on three manifolds arXiv math 0303109 Zbl 1130 53002 P03b Perelman Grisha 2003 Finite extinction time for the solutions to the Ricci flow on certain three manifolds arXiv math 0307245 Zbl 1130 53003See also Edit Mathematics portal Biography portalAncient solution Asteroid 50033 Perelman Homology sphere Hyperbolic manifold Manifold Destiny On The New Yorker article Spherical space form conjecture Thurston elliptization conjecture Uniformization theoremNotes Edit Perfect Rigour A Genius and the Mathematical Breakthrough of the Century by Masha Gessen review the Guardian 27 March 2011 Retrieved 25 July 2022 Company Sudo Null Sudo Null Latest IT News SudoNull Retrieved 25 July 2022 Brilliant amp Reclusive Russian Mathematician Doesn t Need Your Prize Money Discover Magazine Retrieved 25 July 2022 Fields Medals 2006 International Mathematical Union IMU Prizes Archived from the original on June 17 2013 Retrieved April 30 2006 Russian maths genius Perelman urged to take 1m prize BBC News 24 March 2010 Dana Mackenzie 2006 Breakthrough of the year The Poincare Conjecture Proved Science 314 5807 1848 1849 doi 10 1126 science 314 5807 1848 PMID 17185565 The Poincare Conjecture Archived from the original on 5 July 2014 Retrieved 1 May 2014 a b Poslednee net doktora Perelmana Interfax 1 July 2010 Archived from the original on 2 July 2010 Retrieved 1 July 2010 a b Malcolm Ritter 1 July 2010 Russian mathematician rejects 1 million prize AP on PhysOrg Archived from the original on 17 January 2012 Retrieved 15 May 2011 a b c Maths genius declines top prize BBC News 22 August 2006 Archived from the original on 15 August 2010 a b c Osborn Andrew 27 March 2010 Russian maths genius may turn down 1m prize The Daily Telegraph Archived from the original on 30 March 2010 Retrieved 2 July 2010 He has suffered anti Semitism he is Jewish Grigory is pure Jewish and I never minded that but my bosses did McKie Robin 27 March 2011 Perfect Rigour A Genius and the Mathematical Breakthrough of the Century by Masha Gessen review The Guardian Archived from the original on 4 October 2013 Retrieved 23 August 2013 Given that his parents were Jewish Perelman who was born in 1966 was fortunate in those who took up his cause Gessen 2009 p 48 a b John Allen Paulos 29 April 2010 He Conquered the Conjecture The New York Review of Books Eccentric Mathsputin Rejects Million Dollar Prize Fox News Archived from the original on 15 July 2014 Retrieved 8 July 2014 a b International Mathematical Olympiad Imo official org Archived from the original on 2 November 2012 Retrieved 25 December 2012 Gessen 2009 p 45 Young mathematician prize of the St Petersburg Mathematical Society Efimov N V Generation of singularites on surfaces of negative curvature Mat Sb N S 64 106 1964 286 320 Smale Stephen Generalized Poincare s conjecture in dimensions greater than four Ann of Math 2 74 1961 391 406 Freedman Michael Hartley The topology of four dimensional manifolds J Differential Geometry 17 1982 no 3 357 453 Thurston William P Three dimensional manifolds Kleinian groups and hyperbolic geometry Bull Amer Math Soc N S 6 1982 no 3 357 381 John Morgan The Poincare conjecture Lecture at 2006 International Congress of Mathematicians Hamilton Richard S Three manifolds with positive Ricci curvature J Differential Geometry 17 1982 no 2 255 306 Hamilton Richard S Four manifolds with positive curvature operator J Differential Geom 24 1986 no 2 153 179 Hamilton Richard S The Ricci flow on surfaces Mathematics and general relativity Santa Cruz CA 1986 237 262 Contemp Math 71 Amer Math Soc Providence RI 1988 Autobiography of Richard S Hamilton the Shaw Prize Hamilton Richard S 1995 The formation of singularities in the Ricci flow Surveys in Differential Geometry II 7 136 Hamilton Richard S 1997 Four manifolds with positive isotropic curvature Comm Anal Geom 5 1 1 92 doi 10 4310 CAG 1997 v5 n1 a1 Yau Shing Tung Perspectives on geometric analysis Surveys in differential geometry Vol X 275 379 Surv Differ Geom 10 Int Press Somerville MA 2006 Hamilton Richard S Non singular solutions of the Ricci flow on three manifolds Comm Anal Geom 7 1999 no 4 695 729 Colding Tobias H Minicozzi William P II Estimates for the extinction time for the Ricci flow on certain 3 manifolds and a question of Perelman J Amer Math Soc 18 2005 no 3 561 569 Colding Tobias H Minicozzi William P II Width and finite extinction time of Ricci flow Geom Topol 12 2008 no 5 2537 2586 Colding Tobias Holck Minicozzi William P II A course in minimal surfaces Graduate Studies in Mathematics 121 American Mathematical Society Providence RI 2011 xii 313 pp ISBN 978 0 8218 5323 8 Li Peter Yau Shing Tung On the parabolic kernel of the Schrodinger operator Acta Math 156 1986 no 3 4 153 201 Shioya Takashi Yamaguchi Takao Volume collapsed three manifolds with a lower curvature bound Math Ann 333 2005 no 1 131 155 Morgan John Tian Gang The geometrization conjecture Clay Mathematics Monographs 5 American Mathematical Society Providence RI Clay Mathematics Institute Cambridge MA 2014 x 291 pp ISBN 978 0 8218 5201 9 Cao Jianguo Ge Jian A simple proof of Perelman s collapsing theorem for 3 manifolds J Geom Anal 21 2011 no 4 807 869 Kleiner Bruce Lott John Locally collapsed 3 manifolds Asterisque No 365 2014 7 99 ISBN 978 2 85629 795 7 Kleiner Bruce Lott John 2008 Notes on Perelman s papers Geometry amp Topology 12 5 2587 2855 arXiv math 0605667 doi 10 2140 gt 2008 12 2587 S2CID 119133773 a b c d e f Nasar Sylvia Gruber David 21 August 2006 Manifold Destiny A legendary problem and the battle over who solved it The New Yorker Archived from the original on 19 March 2011 Retrieved 21 January 2011 Cao Huai Dong Zhu Xi Ping 2006 Erratum to A complete proof of the Poincare and geometrization conjectures application of the Hamilton Perelman theory of the Ricci flow Asian J Math Vol 10 No 2 165 492 2006 Asian Journal of Mathematics 10 4 663 664 doi 10 4310 ajm 2006 v10 n2 a2 MR 2282358 Cao Huai Dong Zhu Xi Ping 3 December 2006 Hamilton Perelman s Proof of the Poincare Conjecture and the Geometrization Conjecture arXiv math DG 0612069 John W Morgan Gang Tian Ricci Flow and the Poincare Conjecture arXiv math 0607607 Schedule of the scientific program of the ICM 2006 Icm2006 org Archived from the original on 11 February 2010 Retrieved 21 March 2010 Bahri Abbas 2015 Five gaps in mathematics Adv Nonlinear Stud 15 2 289 319 doi 10 1515 ans 2015 0202 S2CID 125566270 Morgan John Tian Gang 2015 Correction to Section 19 2 of Ricci Flow and the Poincare Conjecture arXiv 1512 00699 Bibcode 2015arXiv151200699M John W Morgan Gang Tian Completion of the Proof of the Geometrization Conjecture arXiv 0809 4040 Maths genius urged to take prize BBC News 24 March 2010 Archived from the original on 19 April 2010 Retrieved 25 March 2010 Fields Medal Grigory Perelman PDF International Congress of Mathematicians 2006 22 August 2006 Archived from the original PDF on 3 November 2012 Retrieved 22 August 2006 Mullins Justin 22 August 2006 Prestigious Fields Medals for mathematics awarded New Scientist Prize for Resolution of the Poincare Conjecture Awarded to Dr Grigoriy Perelman PDF Press release Clay Mathematics Institute 18 March 2010 Retrieved 1 May 2014 The Clay Mathematics Institute CMI announces today that Dr Grigoriy Perelman of St Petersburg Russia is the recipient of the Millennium Prize for resolution of the Poincare conjecture Russian math genius ignores 1 million Millennium Prize RIA Novosti 8 July 2010 Archived from the original on 11 June 2010 Retrieved 8 July 2010 Poincare Chair Clay Institute 4 March 2014 Gessen 2009 p 185 Glavnye novosti in Russian RBC Information Systems 22 August 2006 Archived from the original on 16 July 2011 Retrieved 21 March 2010 Nasar Sylvia Gruber David 21 August 2006 Manifold Destiny A legendary problem and the battle over who solved it The New Yorker p 11 Archived from the original on 18 October 2012 Retrieved 21 January 2011 Le genie qui s est retire du monde The genius who has withdrawn from the world Le Point in French 30 September 2010 pp 74 77 Archived from the original on 21 July 2012 Retrieved 15 October 2010 a b Komsomolskaya Pravda found out where Perelman disappears ANNA VELIGZHANINA Nikolai Gerasimov 27 March 2011 Chtoby kupit russkogo hleba Perelman peshkom hodil cherez ves Nyu Jork To buy Russian bread Perelman walked through the whole New York Komsomolskaya Pravda in Russian Archived from the original on 17 September 2012 Retrieved 25 December 2012 a b Anna Veligzhanina 28 April 2011 Intervyu s matematikom Grigoriem Perelmanom Zachem mne million dollarov Ya mogu upravlyat Vselennoj Interview with mathematician Grigori Perelman Why do I need million dollars I can control the world Komsomolskaya Pravda in Russian Archived from the original on 27 December 2012 Retrieved 25 December 2012 Russian math genius answers 1 million question RIA Novosti 29 April 2011 Retrieved 25 December 2012 Masha Gessen 29 April 2011 6 strannyh oshibok v intervyu Perelmana Snob ru Archived from the original on 17 October 2012 Retrieved 8 May 2012 Intervyu Perelmana poddelka Interview with Perelman fake Versii 5 May 2011 Archived from the original on 26 December 2012 Retrieved 25 December 2012 Grigori Perelman s interview full of mismatches English Pravda ru 5 June 2011 Archived from the original on 22 January 2013 Retrieved 25 December 2012 Articles Shattered Genius Brett Forrest Retrieved 25 December 2012 Seven of the week s best reads BBC News 1 September 2012 Archived from the original on 8 March 2013 Retrieved 25 December 2012 Luke Harding 23 March 2010 Grigory Perelman the maths genius who said no to 1m The Guardian References EditAnderson M T 2005 Singularities of the Ricci flow Encyclopedia of Mathematical Physics Elsevier The Associated Press Russian may have solved great math mystery CNN 1 July 2004 Archived from the original on 13 August 2006 Retrieved 15 August 2006 Cao Huai Dong Zhu Xi Ping June 2006 A Complete Proof of the Poincare and Geometrization Conjectures application of the Hamilton Perelman theory of the Ricci flow PDF Asian Journal of Mathematics 10 2 Archived from the original PDF on 14 May 2012 Erratum Revised version December 2006 Hamilton Perelman s Proof of the Poincare Conjecture and the Geometrization Conjecture Collins Graham P 2004 The Shapes of Space Scientific American 291 July 94 103 Bibcode 2004SciAm 291a 94C doi 10 1038 scientificamerican0704 94 PMID 15255593 Gessen Masha 2009 Perfect Rigor A Genius and the Mathematical Breakthrough of the Century Boston Massachusetts Houghton Mifflin Harcourt ISBN 978 0151014064 Jackson Allyn September 2006 Conjectures No More Consensus Forming on the Proof of the Poincare and Geometrization Conjectures PDF Notices of the AMS Kleiner Bruce Lott John 2008 Notes on Perelman s papers Geometry amp Topology 12 5 2587 2855 arXiv math DG 0605667 doi 10 2140 gt 2008 12 2587 S2CID 119133773 Kusner Rob Witnesses to Mathematical History Ricci Flow and Geometry PDF Retrieved 22 August 2006 an account of Perelman s talk on his proof at MIT pdf file also see Sugaku Seminar 2003 10 pp 4 7 for an extended version in Japanese Morgan John W Gang Tian 25 July 2006 Ricci Flow and the Poincare Conjecture arXiv math DG 0607607 External links Edit Media related to Grigori Perelman at Wikimedia Commons Grigori Perelman at the Mathematics Genealogy Project Grigori Perelman s results at International Mathematical Olympiad O Connor John J Robertson Edmund F Grigori Perelman MacTutor History of Mathematics archive University of St Andrews Retrieved from https en wikipedia org w index php title Grigori Perelman amp oldid 1131085122, wikipedia, wiki, book, books, library,

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