January 15, 2008, marks the 100th anniversary of Edward Teller’s birth. This highlight is the first in a series of 10 honoring his life and contributions to science.
THROUGHOUT his career, Edward Teller
displayed a genius for building bridges of discovery between basic
and applied science. In the field of shock physics, papers bearing
his name are on both sides of the bridge.
physics is the study of the behavior of materials as a sharp jump
in density passes through them. The shock can be generated on any
scale—from the action of a supernova to an earthquake, a
hammer blow, or even a single photon. The material affected can
vary as well—from
the substance of stars at high energy density to matter under terrestrial
Teller’s initial interest in shock physics was a natural outgrowth of his work on the quantum dynamics of atoms and molecules. In 1936, Teller and Soviet physicist Lev Landau coauthored a paper proposing a theory about how a sound wave, which essentially is a very weak shock wave, dissipates in a molecular gas. The paper trail leads next to an unpublished but oft-cited paper written in 1941 by Teller and physicist Hans Bethe, “Deviations from Thermal Equilibrium in Shock Waves.” This
work describes the results from a study commissioned by the U.S.
Army to examine how shock waves interact with gases. Their research,
which took into account the microscopic properties of a shocked
medium, proved influential to later studies in many areas, including
the behavior of vehicles reentering the atmosphere.
here, Teller’s renown in the field began to grow. While lecturing at Columbia University, he was approached by Arthur Kantrowitz, a physics graduate student who also worked as an applied scientist at Langley Air Force Base. In his doctoral research, Kantrowitz had developed novel methods for measuring the thermal behaviors of shocks in gases. He asked Teller to sponsor his dissertation. In Memoirs, Teller says, “Arthur knew much more about the subject than I did. But when I started to demur . . . Arthur pointed out that my work with Landau, and a recent note that Bethe and I had published, made it impossible for me to deny all knowledge of the subject.” Teller
agreed to be his advisor and thus became a mentor in the arena
of shock physics. Kantrowitz later became a leading expert in the
field of hypersonic hydrodynamics.
the discovery of fission was announced in 1939, Teller was intrigued
and began to consider the potential uses of nuclear energy produced
in both fission and fusion reactions. In 1942, he joined the Manhattan
Project, to help develop the nation’s first atomic bomb.
From the beginning, shock physics was an important part of that
research as scientists worked to understand how the shock waves
produced by high explosives and nuclear energy release would affect
the various materials being used in a nuclear weapon.
Teller’s interest in high-energy-density physics and shock physics continued after the war. For example, in 1949, he coauthored the important paper “Magneto-Hydrodynamic Shocks” with physicist Frederick de Hoffman, generalizing shock “rules” to
relativistic magnetohydrodynamics, which studies the interaction
of density and magnetic-field pulses in electrically conducting
liquids or gases, such as molten metal or plasma. Furthermore,
Teller initiated significant work during and after the war on equation-of-state
models, a key ingredient in understanding shock propagation.
is not surprising then, given the shock physics thread weaving
through his life at the intersection of basic and applied science,
that Lawrence Livermore National Laboratory—the laboratory cofounded by Teller and Ernest O. Lawrence in 1952—should become known for its shock physics experiments and the computer codes and simulations based on such data. Livermore’s early shock physics experiments allowed scientists to study the behavior of gases, fluids, and solids as they are exposed to shock waves. High-fidelity data from these experiments improve the accuracy of simulations used to replicate past underground nuclear tests and thus are crucial to today’s Stockpile Stewardship Program, which ensures the safety and reliability of the nation’s
|Results from Livermore’s three-dimensional hydrodynamics model of a red giant star show that, deep in the star’s interior, hydrogen-rich clouds (red) float above the hydrogen-burning shell (blue).
||The two-stage gas gun at the Joint Actinide Shock Physics Experimental Research Facility in Nevada is one method used to perform shock physics experiments.
(Photograph courtesy of the Nevada Test Site.)
Shock physics continues to be an important research area at the Laboratory. Experimental platforms such as gas guns, lasers, and diamond anvil cells allow researchers to elucidate the equations of state of shocked materials and improve their understanding of complex materials such as plutonium. (See New Routes to High Temperatures and Pressures.)
In 1994, shock experiments at Livermore yielded the first observation
of fluid metallic hydrogen. Using gas guns and lasers, Livermore
scientists produce shocks that create extraordinarily high pressures,
mimicking the extreme conditions in an explosion, the detonation
of a nuclear weapon, an inertial fusion experiment, a star, or
the impact of a large meteorite, were one to hit the Earth. Shock
physics experiments helped determine the melting point for iron
in Earth’s core, while data about hydrogen and other molecular
fluids such as water are allowing scientists to better understand
the interiors of giant planets in our solar system.
it was defining the interactions of sound waves with gases or exploring
the behavior of metals under extreme conditions, Teller excelled
at making connections between theory and applied science, including
the field of shock physics. This approach—taking what is known and what can be done, and pushing beyond—is
one that continues at Lawrence Livermore to this day.
Key Words: Edward Teller, magnetohydrodynamics, Manhattan Project, shock physics.
For further information contact Stephen B. Libby (925) 422-9785 (email@example.com).
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