Gelbart's early interest in science was inspired by his time as an undergraduate researcher in the
molecular spectroscopy group of
William Klemperer at
Harvard. As a graduate student at the
University of Chicago, with his mentors
Stuart A. Rice,
Karl Freed, and
Joshua Jortner, he developed the modern theory of non-radiative processes ("radiationless transitions") in molecular photophysics. He was a US National Science Foundation/NATO Postdoctoral Fellow at the,
University of Paris in 1971, and a Miller Institute Postdoctoral Fellow at
UC Berkeley in 1972, during which time he switched fields and formulated a general theory of collision-induced optical properties of simple fluids. He was appointed Assistant Professor of Chemistry, at UC Berkeley in 1972, continuing his researches on the
quantum mechanical theory of
molecular spectroscopy and on the
statistical mechanical theory of intermolecular and multiple light
scattering in liquids away from and near their
critical points. He moved to UCLA as Associate Professor of Chemistry in 1975, and was promoted to full Professor in 1979 and to Distinguished Professor in 1999. He was Chair of the Department of Chemistry and Biochemistry at UCLA from 2000-2004 and has been a member of UCLA's California NanoSystems Institute since 2004 and of its Molecular Biology Institute from 2008. At UCLA he became a leader in the then-emerging fields of "
complex fluids" and "
soft matter physics". Shortly after moving there he began a 40-year collaboration with Avinoam Ben-Shaul on
statistical-thermodynamic models of
liquid crystal systems,
polymer and
polyelectrolyte (in particular,
DNA) solutions, and
colloidal suspensions, and on the
self-assembly theory of
micelles,
surfactant monolayers, and biological membranes. During a sabbatical year in 1998-99 at the
Institute for Theoretical Physics in
UC Santa Barbara and at the
Curie Institute in
Paris, Gelbart became deeply intrigued by
viruses and over the course of the next several years, with his
UCLA colleague Charles Knobler, established a laboratory to investigate simple viruses outside their hosts and isolated in test tubes. Early results included: the first measurement of
pressure inside
DNA viruses, establishing that it is as high as tens of
atmospheres depending on
genome length and ambient salt concentrations; and the demonstration that
capsid proteins from certain viruses are capable of complete
in vitro packaging of a broad range of lengths of
heterologous RNA. This work, along with that of several other groups in the
United States and
Europe, helped launch the field of "physical virology". Most recently he moved his viruses from test tubes to
host cells, and from
wildtype viruses to artificial viruses and
virus-like particles, engineered for purposes of delivering
self-replicating RNA genes,
RNA vaccines, and therapeutic
microRNA to targeted mammalian cells. == Awards ==