Paul Cohen (mathematician)

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**Paul J. Cohen**
Born	April 2, 1934 Long Branch, New Jersey
Died	March 23, 2007 Stanford, California
Field	Mathematics
Institution	Stanford University
Alma mater	University of Chicago
Academic advisor	Antoni Zygmund
Notable students	Peter Sarnak
Known for	Forcing Continuum hypothesis
Notable prizes	Fields Medal (1966) Bôcher Prize (1964) National Medal of Science (1967)

Paul Joseph Cohen (April 2, 1934 – March 23, 2007^[1]) was an American mathematician. He was born in Long Branch, New Jersey and graduated in 1950 from Stuyvesant High School in New York City.

He then studied at Brooklyn College for his bachelor's degree of 1953. At the University of Chicago, he received his master's degree in 1954 and his PhD in 1958 under supervision of Antoni Zygmund.

He is noted for inventing a technique called forcing which he used to show that neither the continuum hypothesis (CH) nor the axiom of choice can be proved from the standard Zermelo-Fraenkel axioms (ZF) of set theory. In conjunction with the earlier work of Gödel, this showed that both these statements are independent of ZF: they can be neither proved nor disproved from these axioms. In this sense CH is undecidable, and probably the most famous example of a natural statement independent from the conventional axioms of set theory.

For his result on CH he won the Fields Medal in 1966 and the National Medal of Science in 1967.

He was also awarded the Bôcher Memorial Prize in 1964 for his paper "On a conjecture of Littlewood and idempotent measures".

He was a professor at Stanford University, where he supervised Peter Sarnak's dissertation, among others.

His twin sons Steven and Eric played the Dancing Twins on the TV show Ally McBeal.^{[citation needed]}

[edit] On the continuum hypothesis

"A point of view which the author [Cohen] feels may eventually come to be accepted is that CH is obviously false. The main reason one accepts the axiom of infinity is probably that we feel it absurd to think that the process of adding only one set at a time can exhaust the entire universe. Similarly with the higher axioms of infinity. Now $\aleph_1$ is the cardinality of the set of countable ordinals and this is merely a special and the simplest way of generating a higher cardinal. The set $C$ [the continuum] is, in contrast, generated by a totally new and more powerful principle, namely the power set axiom. It is unreasonable to expect that any description of a larger cardinal which attempts to build up that cardinal from ideas deriving from the replacement axiom can ever reach $C$ . Thus $C$ is greater than $\aleph_n, \aleph_\omega, \aleph_a$ , where $a = \aleph_\omega$ , etc. This point of view regards $C$ as an incredibly rich set given to us by one bold new axiom, which can never be approached by any piecemeal process of construction. Perhaps later generations will see the problem more clearly and express themselves more eloquently."

Cohen, P. Set Theory and the Continuum Hypothesis p.151.

[edit] Footnotes

^ A public announcement of his death has been made by the American Mathematical Society [1].

[edit] External links

O'Connor, John J., and Edmund F. Robertson. "Paul Joseph Cohen". MacTutor History of Mathematics archive.
Stanford Mathematics - Faculty
Paul Joseph Cohen at the Mathematics Genealogy Project
paulcohen.org - a commemorative website celebrating the life of Paul Cohen