Nicholas Constantine Metropolis
June 11, 1915
|Died||October 17, 1999 (aged 84)|
|Alma mater||University of Chicago|
|Awards||Computer Pioneer Award (1984)|
|Institutions||Los Alamos National Laboratory|
Metropolis received his BSc (1937) and PhD (1941) degrees in physics at the University of Chicago. Shortly afterwards, Robert Oppenheimer recruited him from Chicago, where he was at the time collaborating with Enrico Fermi and Edward Teller on the first nuclear reactors, to the Los Alamos National Laboratory. He arrived in Los Alamos in April 1943, as a member of the original staff of fifty scientists.
After World War II
After World War II, he returned to the faculty of the University of Chicago as an assistant professor. He came back to Los Alamos in 1948 to lead the group in the Theoretical Division that designed and built the MANIAC I computer in 1952 that was modeled on the IAS machine, and the MANIAC II in 1957. (He chose the name MANIAC in the hope of stopping the rash of such acronyms for machine names, but may have, instead, only further stimulated such use.) (John von Neumann thought this acronym was too frivolous.)  From 1957 to 1965 he was Professor of Physics at the University of Chicago and was the founding Director of its Institute for Computer Research. In 1965 he returned to Los Alamos where he was made a Laboratory Senior Fellow in 1980.
Monte Carlo method
At Los Alamos, in the 1950s, a group of researchers led by Metropolis, including John von Neumann and Stanislaw Ulam, developed the Monte Carlo method. Generally speaking, the Monte Carlo method is a statistical approach to solve deterministic many-body problems. In 1953 Metropolis co-authored the first paper on a technique that was central to the method now known as simulated annealing. This landmark paper showed the first numerical simulations of a liquid. The algorithm for generating samples from the Boltzmann distribution was later generalized by W.K. Hastings to become the Metropolis-Hastings algorithm. He is credited as part of the team that came up with the name Monte Carlo method in reference to a colleague's relative's love for the casinos of Monte Carlo. Monte Carlo methods are a class of computational algorithms that rely on repeated random sampling to compute their results. In statistical mechanics applications prior to the introduction of the Metropolis algorithm, the method consisted of generating a large number of random configurations of the system, computing the properties of interest (such as energy or density) for each configuration, and then producing a weighted average where the weight of each configuration is its Boltzmann factor, , where is the energy, is the temperature, and is the Boltzmann constant. The key contribution of the Metropolis paper was the idea that
Instead of choosing configurations randomly, then weighting them with exp(−E/kT), we choose configurations with a probability exp(−E/kT) and weight them evenly.— Metropolis et al., 
Associations and honors
Metropolis was a member of the American Academy of Arts and Sciences, the Society for Industrial and Applied Mathematics and the American Mathematical Society. In 1987 he became the first Los Alamos employee honored with the title "emeritus" by the University of California. Metropolis was also awarded the Pioneer Medal by the Institute of Electrical and Electronics Engineers, and was a fellow of the American Physical Society.
In his memoirs, Stanislaw Ulam remembers that a small group, including himself, Metropolis, Calkin, Konopinski, Kistiakowsky, Teller and von Neumann, spent several evenings at Los Alamos playing poker. They played for very small sums, but: "Metropolis once described what a triumph it was to win ten dollars from John von Neumann, author of a famous treatise on game theory. He then bought his book for five dollars and pasted the other five inside the cover as a symbol of his victory." In another passage of his book, Ulam describes Metropolis as "a Greek-American with a wonderful personality."
- ΒΑΡΒΟΓΛΗΣ, Χ (March 16, 2008). Ελληνική σφραγίδα στο πρώτο μηχανοργανωμένο πείραμα. Athens, Greece. Retrieved December 6, 2012.
- Metropolis, Nicholas Constantine (1915–1999) Eric Weisstein's World of Biography
- Balazs, N. L.; Browne, J. C.; Louck, J. D.; Strottman, D. S. (October 2000). "Obituary: Nicholas Constantine Metropolis". Physics Today. 53 (10): 100–101. Bibcode:2000PhT....53j.100B. doi:10.1063/1.1325208.
- Nicolas Metropolis.The Beginning of the Monte Carlo Method. Los Alamos Science, No. 15, Page 125.
- N. Metropolis; A.W. Rosenbluth; M.N. Rosenbluth; A.H. Teller & E. Teller (1953). "Equation of State Calculations by Fast Computing Machines". Journal of Chemical Physics. 21 (6): 1087–1092. Bibcode:1953JChPh..21.1087M. doi:10.1063/1.1699114.
- Nicholas Metropolis Award for Outstanding Doctoral Thesis Work in Computational Physics
- Nicholas Metropolis on IMDb
- Nick Metropolis dead at 84. Los Alamos National Laboratory Daily News Bulletin. Oct 19, 1999.
- S. M. Ulam, Adventures of a mathematician, California University press
- "My Erdős Number is Five". barbecuejoe.com.
11. Ioannis A. Daglis: Από τον ENIAC στα laptop και από τον Nicholas Metropolis στον Nicholas Negroponte – 60 χρόνια από την επανάσταση των κομπιούτερ [From ENIAC to Laptops and from Nicholas Metropolis to Nicholas Negroponte - 60 years from the computer revolution], Geotropio (in Greek), December 2, 2006.
|Wikiquote has quotations related to: Nicholas Metropolis|
- 1993 Audio Interview with Nicholas Metropolis by Richard Rhodes Voices of the Manhattan Project
- Oral history interview with Nicholas C. Metropolis, Conducted by William Aspray at Charles Babbage Institute, University of Minnesota. Metropolis, the first director of computing services at Los Alamos National Laboratory, discusses John von Neumann's work in computing. Most of the interview concerns activity at Los Alamos: how von Neumann came to consult at the laboratory; his scientific contacts there, including Metropolis, Robert Richtmyer, and Edward Teller; von Neumann's first hands-on experience with punched card equipment; his contributions to shock-fitting and the implosion problem; interactions between and comparisons of von Neumann and Enrico Fermi; and the development of Monte Carlo techniques. Other topics include: the relationship between Alan Turing and von Neumann; work on numerical methods for non-linear problems; and the ENIAC calculations done for Los Alamos.
- Francis Harlow and Nicolas Metropolis. Computing and Computers -- Weapons Simulation Leads to the Computer Era. Los Alamos Science No. 7, Page 132.
- Herbert Anderson. Metropolis, Monte Carlo and the MANIAC. Los Alamos Science No. 14, Page 69.