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William Paul Thurston (October 30, 1946August 21, 2012) was an American mathematician. He was a pioneer in the field of low-dimensional topology and was awarded the Fields Medal in 1982 for his contributions to the study of 3-manifolds.
Thurston was a professor of mathematics at Princeton University, University of California, Davis, and Cornell University. He was also a director of the Mathematical Sciences Research Institute.
He received his bachelor's degree from New College in 1967 as part of its inaugural class. For his undergraduate thesis, he developed an intuitionism foundation for topology.See p. 3 in Following this, he received a doctorate in mathematics from the University of California, Berkeley under Morris Hirsch, with his thesis Foliations of Three-Manifolds which are Circle Bundles in 1972.
In 1974, Thurston was appointed a full professor at Princeton University. He returned to Berkeley in 1991 to be a professor (1991-1996) and was also director of the Mathematical Sciences Research Institute (MSRI) from 1992 to 1997. He was on the faculty at UC Davis from 1996 until 2003, when he moved to Cornell University.
Thurston was an early adopter of computing in pure mathematics research. He inspired Jeffrey Weeks to develop the SnapPea computing program.
During Thurston's directorship at MSRI, the institute introduced several innovative educational programs that have since become standard for research institutes.
His Ph.D. students include Danny Calegari, Richard Canary, Benson Farb, William Floyd, David Gabai, William Goldman, Richard Kenyon, Steven Kerckhoff, Yair Minsky, Igor Rivin, Oded Schramm, Richard Schwartz, and Jeffrey Weeks.
In fact, Thurston resolved so many outstanding problems in foliation theory in such a short period of time that it led to an exodus from the field, where advisors counselled students against going into foliation theory, because Thurston was "cleaning out the subject" (see "On Proof and Progress in Mathematics", especially section 6).
Inspired by their work, Thurston took a different, more explicit means of exhibiting the hyperbolic structure of the figure-eight knot complement. He showed that the figure-eight knot complement could be decomposed as the union of two regular ideal hyperbolic tetrahedra whose hyperbolic structures matched up correctly and gave the hyperbolic structure on the figure-eight knot complement. By utilizing Wolfgang Haken's normal surface techniques, he classified the incompressible surfaces in the knot complement. Together with his analysis of deformations of hyperbolic structures, he concluded that all but 10 Dehn surgery on the figure-eight knot resulted in irreducible, non-Haken manifold non-Seifert-fibered 3-manifolds. These were the first such examples; previously it had been believed that except for certain Seifert fiber spaces, all irreducible 3-manifolds were Haken. These examples were actually hyperbolic and motivated his next theorem.
Thurston proved that in fact most Dehn fillings on a cusped hyperbolic 3-manifold resulted in hyperbolic 3-manifolds. This is his celebrated hyperbolic Dehn surgery theorem.
To complete the picture, Thurston proved a hyperbolization theorem for . A particularly important corollary is that many knots and links are in fact hyperbolic. Together with his hyperbolic Dehn surgery theorem, this showed that closed hyperbolic 3-manifolds existed in great abundance.
The hyperbolization theorem for Haken manifolds has been called Thurston's Monster Theorem, due to the length and difficulty of the proof. Complete proofs were not written up until almost 20 years later. The proof involves a number of deep and original insights which have linked many apparently disparate fields to 3-manifolds.
Thurston was next led to formulate his geometrization conjecture. This gave a conjectural picture of 3-manifolds which indicated that all 3-manifolds admitted a certain kind of geometric decomposition involving eight geometries, now called Thurston model geometries. Hyperbolic geometry is the most prevalent geometry in this picture and also the most complicated. The conjecture was proved by Grigori Perelman in 2002–2003.
Thurston received the Fields Medal in 1982 for "revolutionizing the study of topology in 2 and 3 dimensions, showing interplay between analysis, topology, and geometry" and "contributing the idea that a very large class of closed 3-manifolds carry a hyperbolic structure."
In 2005, Thurston won the first American Mathematical Society Book Prize, for Three-dimensional Geometry and Topology.
The prize "recognizes an outstanding research book that makes a seminal contribution to the research literature". He was awarded the 2012 Leroy P. Steele Prize by the American Mathematical Society for seminal contribution to research. The citation described his work as having "revolutionized 3-manifold theory".
Thurston died on August 21, 2012, in Rochester, New York, of a sinus mucosal melanoma that was diagnosed in 2011." Department mourns loss of friend and colleague, Bill Thurston", Cornell University
Research
Foliations
His early work, in the early 1970s, was mainly in foliation theory. His more significant results include:
The geometrization conjecture
His later work, starting around the mid-1970s, revealed that hyperbolic geometry played a far more important role in the general theory of 3-manifolds than was previously realised. Prior to Thurston, there were only a handful of known examples of hyperbolic 3-manifolds of finite volume, such as the Seifert–Weber space. The independent and distinct approaches of Robert Riley and Troels Jørgensen in the mid-to-late 1970s showed that such examples were less atypical than previously believed; in particular their work showed that the figure-eight knot knot complement was hyperbolic link. This was the first example of a hyperbolic knot.
Density conjecture
Thurston and Dennis Sullivan generalized Lipman Bers' density conjecture from singly degenerate Kleinian surface groups to all finitely generated in the late 1970s and early 1980s. The conjecture states that every finitely generated Kleinian group is an algebraic limit of geometrically finite Kleinian groups, and was independently proven by Ohshika and Namazi–Souto in 2011 and 2012 respectively.
Orbifold theorem
In his work on hyperbolic Dehn surgery, Thurston realized that orbifold structures naturally arose. Such structures had been studied prior to Thurston, but his work, particularly the next theorem, would bring them to prominence. In 1981, he announced the orbifold theorem, an extension of his geometrization theorem to the setting of 3-orbifolds. Two teams of mathematicians around 2000 finally finished their efforts to write down a complete proof, based mostly on Thurston's lectures given in the early 1980s in Princeton. His original proof relied partly on Richard S. Hamilton's work on the Ricci flow.
Awards and honors
In 1976, Thurston and James Harris Simons shared the Oswald Veblen Prize in Geometry.
Personal life
Thurston and his first wife, Rachel Findley, had three children: Dylan, Nathaniel, and Emily. Dylan was a MOSP participant (1988–90) and is a mathematician at Boston College. Thurston had two children with his second wife, Julian Muriel Thurston: Hannah Jade and Liam.
Selected publications
See also
Further reading
External links
Categories: 1946 Births, 2012 Deaths, New College Of Florida Alumni, University Of California, Berkeley Alumni, American Topologists, Differential Geometers, Hyperbolic Geometers, Members Of The United States National Academy Of Sciences, 20th-century American Mathematicians, 21st-century American Mathematicians, Fields Medalists, Princeton University Faculty, University Of California, Berkeley Faculty, Cornell University Faculty, University Of California, Davis Faculty, Institute For Advanced Study Visiting Scholars, Mathematicians From Washington, D.c.
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