Gregory A. Voth

Gregory A. Voth is a theoretical chemist and Haig P. Papazian Distinguished Service Professor of Chemistry at the
University of Chicago. He is also a professor of the James Franck Institute and the Institute for Biophysical Dynamics.

Education

He received his bachelor's degree from University of Kansas in 1981 with highest distinction and honors and a Ph.D. in theoretical chemistry from the California Institute of Technology in 1987. His doctoral advisor was Rudolph A. Marcus. He was also an IBM Postdoctoral Fellow at the University of California, Berkeley from 1987-1989. At Berkeley, his postdoctoral advisors were William Hughes Miller and David Chandler.

Career

Professor Voth is interested in the development and application of theoretical and computational methods to study problems involving the structure and dynamics of complex condensed phase systems, including proteins, membranes, liquids, and materials. He has developed a method known as “multiscale coarse-graining” in which the resolution of the molecular-scale entities is reduced into simpler structures, but key information on their interactions is accurately retained so the resulting computer simulation can accurately and efficiently predict the properties of large assemblies of complex molecules such as lipids and proteins. This method is multiscale, meaning it describes complex condensed phase and biomolecular systems from the molecular scale to the mesoscale and ultimately to the macroscopic scale. Professor Voth’s other research interests include the study of charge transport in aqueous systems and biomolecules – a fundamental process in living organisms and other systems that have been poorly understood because of its complexity. He also studies the exotic behavior of room-temperature ionic liquids and other complex materials such nanoparticle self-assembly, polymer electrolyte membranes, and electrode-electrolyte interfaces in energy storage devices. In the earlier part of his career, Professor Voth extensively developed and applied new methods to study quantum and electron transfer dynamics in condensed phase systems-much of this work was based on the Feynman path integral description of quantum mechanics.
As of 07/11/2025, Prof. is the author or co-author of more than 650 peer-reviewed scientific articles and has mentored more than 200 postdoctoral fellows and graduate students.

Honors and awards

Procter and Gamble Award for Outstanding Research in Physical Chemistry, ACS, 1985
Herbert Newby McCoy Award, California Institute of Technology, 1986
Francis and Milton Clauser Doctoral Prize, California Institute of Technology, 1987
Camille and Henry Dreyfus Distinguished New Faculty Award, 1989
David and Lucile Packard Foundation Fellowship in Science and Engineering, 1990–1995
Presidential Young Investigator Award, 1991–1996
Alfred P. Sloan Foundation Research Fellow, 1992–1994
Camille Dreyfus Teacher-Scholar Award, 1994–1999
IBM Corporation Faculty Research Award, 1997–1999, 2003–2005
Fellow of the American Physical Society, 1997
Fellow of the American Association for the Advancement of Science, 1999
National Science Foundation Creativity Award, 1998–2002
Miller Visiting Professorship, University of California, Berkeley, 2003
Received John Simon Guggenheim Fellowship, 2004–2005
University of Utah Distinguished Scholarly and Creative Research Award, 2008
Fellow of the American Chemical Society, 2009
Fellow of the Biophysical Society, 2012
Elected to the International Academy of Quantum Molecular Science, 2013
ACS Division of Physical Chemistry Award in Theoretical Chemistry, 2013
Stanislaw M. Ulam Distinguished Scholar, Los Alamos National Laboratory, 2014
ACS Joel Henry Hildebrand Award in the Theoretical and Experimental Chemistry of Liquids, 2019
S F Boys-A Rahman Award Winner, 2019. Royal Society of Chemistry
Biophysical Society Innovation Award, 2021. Biophysical Society
Satish Dhawan Distinguished Visiting Professor, Indian Institute of Science, 2023
National Award in Theoretical Chemistry, American Chemical Society, 2025