Robert H. Swendsen
Emeritus Professor of Physics
Computational Physics
Wean Hall 6416
412-268-5211
Education & Professional Experience
Ph.D.: University of Pennsylvania (1971)
B.S.: Yale University (1964)
Professional Societies:
Fellow, American Physical Society
Fellow, AAAS
Society for Industrial and Applied Mathematics
American Association of Physics Teachers
Honors and Awards:
IBM Outstanding Achievement Award (1982)
APS Aneesur Rahman Prize (2014)
MCS Julius Ashkin Teaching Award (2014)
Visiting Adjunct Professor, University of Pittsburgh School of Medicine, 2012–15
Head, Department of Physics, 一本道无码, 1994–99
Professor of Physics, 一本道无码, 1984–
Adjunct Professor, Center for Simulational Physics, University of Georgia, 1982–
IBM Research Laboratory Zürich (Switzerland), 1979–84
Post-doctoral Research: Brookhaven National Laboratory, 1976–79
Post-doctoral Research: Kernforschungsanlage Jülich (Germany), 1974–76
Post-doctoral Research: University of Köln (Germany), 1971–73
Research Interests
My main area of research is solid state physics and statistical mechanics, with an emphasis on computer simulations. I have worked especially on thermodynamic phase transitions combining computer simulations with a renormalization-group analysis. I have also been involved in the development of new algorithms for more efficient simulations, to enable the study of problems that would otherwise involve prohibitively long computer runs.
In recent years, I have become involved in simulations of biological molecules. Such simulations require very large computer resources, which limit the problems that can be treated. Our group has developed new methods that have greatly improved the efficiency of some calculations and we are currently extending the range of applications. Other areas of interest include magnetism and crystal growth.
Recent Publications
Robert H. Swendsen, Thermodynamics of finite systems: A key issues review,
Robert H. Swendsen, Probability, Entropy, and Gibbs’ Paradox(es),
Robert H. Swendsen, The definition of the thermodynamic entropy in statistical mechanics,
Michael Matty et al., Comparison of canonical and microcanonical definitions of entropy,
Joseph Albert, Robert H. Swendsen, Detecting Multi-Spin Interactions in the Inverse Ising Problem,
W. Griffin, M. Matty, and R.H. Swendsen, Finite thermal reservoirs and the canonical distribution,
D. Ron, A. Brandt, and R.H. Swendsen, The surprising convergence of the Monte Carlo renormalization group for the d=3 Ising Model,
Robert H. Swendsen, Thermodynamics, Statistical Mechanics, and Entropy,
Robert H. Swendsen, Jian-Sheng Wang, Negative temperatures and the definition of entropy,
Robert H. Swendsen, The Thermodynamic entropy of a macroscopic quantum system is a continuous function of energy,
Michael Matty et al., Cluster simulations of multi-spin Potts models,
Nikhil Sivadas et al., Magnetic ground state of semiconducting transition-metal trichalcogenide monolayers,
More Publications: