Historical Faculty Information
Physics Department History
The Early Years, 1891 through
the 1930's
Stanford University opened in 1891, with the
Department of Physics among the very first departments at the new
University. As the Register for 1891-92 indicates, five courses in
physics -- both laboratory and classroom -- were offered to the
inaugural class of enthusiastic young men and women. Research was not
far behind, however. By the early 1900s, research on X-rays had begun,
first under the direction of David Webster, and later under Paul
Kirkpatrick. It was not until the arrival of Swiss physicist Felix
Bloch, however, in 1934, that physics research at Stanford truly caught
fire. A refugee from the Nazis, Bloch was only 28 years old when he
answered David Webster's invitation to join the Stanford faculty. Yet
he had already made extraordinary contributions to physics, through his
theory of electron transport, the Bethe-Bloch equation of the stopping
power of fast particles in matter, the theory of ferromagnetism, his
invention of spin waves, and Bloch walls. Soon after he arrived at
Stanford, Bloch, together with Berkeley physicist Robert Oppenheimer,
organized a joint seminar on theoretical physics that met alternately
at Stanford and Berkeley. Many of the leading physicists of Europe and
the United States traveled to the West Coast to speak at these
seminars, and many came to Stanford as summer visitors. By the
mid-1930s, Stanford was recognized as an important center for physics,
despite the fact that geographically it was considered far removed from
the center of "civilization!"
The Middle 1930's through the
1960's
Encouraged initially by Enrico Fermi to do
experimental physics because, among other things, it was "fun," in 1938
Bloch (in collaboration with Luis Alvarez) made the first experimental
measurement of the magnetic moment of the neutron, marking the
beginning of the work for which he is perhaps best known. By the end of
the Second World War, Bloch, working with Bill Hansen and Martin
Packard, had succeeded in observing nuclear magnetic resonance (NMR) in
condensed matter by the method of nuclear induction. For these
discoveries, and the discoveries made with this technique, Bloch shared
the 1952 Nobel Prize in Physics with Harvard's Edward Purcell. It was
Stanford's first Nobel Prize. NMR has since become the most important
spectroscopic technique in chemistry and biology, and magnetic
resonance imaging (MRI), an imaging technique based upon it, is
considered the greatest advance in medical imaging since the discovery
of X-rays in 1895.
In the late 1930s, Research Associates Russell and
Sigurd Varian, working in collaboration with their mentor, Professor
Bill Hansen, invented the klystron, a high-power microwave source and
amplifier. The klystron was rapidly developed during World War II for
use in radar, navigation, and blind-landing devices for aircraft. But
Hansen, whose own contribution to the klystron was the resonant cavity
called a rhumbatron, was interested in using the klystron for the
acceleration of particles. And by 1947 he had built the first linear
electron accelerator, the Mark I, which accelerated electrons to 6 MeV.
Then, just four years later, Edward Ginzton and Marvin Chodorow
completed the Mark III, a 1-GeV electron accelerator. It was the Mark
III that allowed Robert Hofstadter to study the charge and magnetic
structure of nuclei and nucleons, work that earned him the 1961 Nobel
Prize in Physics.
Stanford Linear Accelerator
Center
Hansen's work has continued to be highly fruitful.
In 1967, the Stanford Linear Accelerator Center (SLAC), a national
facility designed to hold a new two-mile accelerator, was completed and
running, and nine years later, Stanford's Burton Richter shared the
Nobel Prize for the discovery of the Psi/J-particle. In 1988, Mel
Schwartz, a long-time member of the department, shared the Nobel Prize
for his discovery of the muon neutrino, though this work had been done
earlier at Brookhaven. Then, in 1990, Dick Taylor shared the Nobel
Prize for his studies of deep inelastic scattering, which showed the
existence of point-like objects in nucleons, now recognized as quarks.
In 1995, Martin Perl won the Nobel Prize in Physics for his discovery
of a new elementary particle known as the tau lepton.
Quantum Mechanics and
Leonard Schiff
Shifting focus to another area of investigation,
we come to Leonard Schiff, whose book, Quantum Mechanics, published in
1949, provided the means by which several generations of physicists
learned this subject. Schiff had become department chair in 1948 and,
together with Bloch, had formed an appointments committee that gave the
department clear international stature in short order. A nuclear
physics group was built up under Walter Meyerhof and Stanley Hanna; an
Institute for Theoretical Physics was soon established; and, under the
direction of Wolfgang Panofsky and Robert Hofstadter, the High Energy
Physics Laboratory was organized.
In 1971, Sandy Fetter and Dirk Walecka published
Quantum Theory of Many-Particle Systems and later Theoretical Mechanics
of Particles and Continua, sustaining the line of superb graduate texts
initiated with Schiff's Quantum Mechanics. Both volumes evolved from
the authors' elegant and inspiring graduate lectures on these subjects,
modeled on the Schiff dictum: excellence in teaching goes hand-in-hand
with excellence in research -- a theme still emphasized in the
department today.
Low Temperature Physics
Paul Kirkpatrick's pioneering research on
reflecting X-ray optics and holography continued throughout the 1950s.
In the late '50s Bill Little and, shortly thereafter, Bill Fairbank
joined the department to establish low-temperature laboratories. In
1961, Fairbank and Bascom Deaver discovered flux quantization while
Little and Ron Park discovered quantum interference effects in
superconductors, both precursors to the SQUID. Fairbank's earlier work
on high-Q cavities led to his proposal in 1961 for a superconducting
accelerator, eventually brought to reality at Stanford in collaboration
with Mike McAshan, Alan Schwettman, Todd Smith, John Turneaure and
Perry Wilson. This, and the klystrons of the earlier era, have become
the enabling technologies for many of today's accelerators relying on
superconducting cavities like CEBAF and LEP at CERN, as well as linear
colliders currently under discussion.
Little's controversial proposal in 1964 for a
high-temperature, organic superconductor stimulated much interest in
low-dimensional and organic conductors. This was followed in 1969 by
the discovery of two-dimensional superconductors and, in 1975 at
Stanford, polymeric superconductors. We now know of many organic
superconductors; studies of these, the fullerenes, and the
high-transition temperature ceramic superconductors have become a
vigorous area of condensed-matter research.
Art Schawlow joined the Stanford faculty shortly
after he invented the laser, in collaboration with Charles Townes, at
Bell Laboratories in 1958. An exciting time followed, as new and
powerful advances were made in optics and laser spectroscopy. Ted
Hänsch and Schawlow pioneered the development of Doppler-free
high-precision spectroscopy and other powerful laser techniques that
have made possible new and fundamental studies of atomic and molecular
systems. In 1981 Schawlow shared the Nobel Prize for physics for the
discovery of these new techniques in laser spectroscopy. Since then,
Steve Chu, who won the Nobel Prize in physics in 1997, has taken these
optical techniques to yet another dimension, with "optical molasses"
(the cooling of particles in a light field to microkelvin
temperatures), the laser trapping of atoms, and the development of
optical tweezers for biological experiments. Recently, Mark Kasevich
has returned to Stanford from several years at Yale. His very broad
interests include both pure and applied physics; they range from
Bose-Einstein condensates in optical lattices (which provide an
important analogy to condensed-matter systems) to high-precision
gravimeters and gyroscopes based on atomic fountains and
interferometers.
Astrophysics
Astrophysics is on the upswing in the department,
and now includes theoretical studies on a wide range of exotic topics
complemented by enterprising experimental programs. These have included
participation in the Gamma-ray astronomical observatory, EGRET
(initiated by Hofstadter in the 1970s and subsequently under Peter
Michelson's direction), and the current development of GLAST, a
next-generation large-area orbiting gamma-ray telescope, also led by
Michelson. Searches for dark matter in the form of elementary particles
such as WIMPs (weakly interacting massive particles) have been
developed by Blas Cabrera. The calculations of primordial elemental
abundances by Wagoner, the discovery of giant luminous arcs due to
gravitation lensing by Petrosian, and the elucidation of inflation and
phase transitions in cosmology by Linde are major cornerstones in
cosmology and astrophysics. Roger Romani's research focuses on black
holes and neutron stars and he has been instrumental in initiating
Stanford's membership in the Hobby-Eberly Telescope, a 10-meter
spectroscopic survey telescope at MacDonald Observatory in Texas. Sarah
Church, an experimentalist working on observations of the cosmic
microwave background, joined our department in 1999, further enhancing
our astrophysics program. Phillip Scherrer leads an ongoing major study
of solar physics relying on data from NASA satellites. In 2002,
Stanford received a major gift that led to the formation of the Kavli
Institute for Astrophysics and Cosmology (KIPAC), based both at SLAC
and in the Physics Department. Roger Blandford became the
Director of KIPAC, and Steven Kahn the Deputy Director, in 2003.
In 2004, Tom Abel, a theoretical astrophysicist, and Steven Allen, an
experimental astrophysicist, were hired with joint faculty appointments
in Physics and SLAC.
Gravity Probe B
A new experimental test of the general theory of
relativity was proposed in a classic paper by Schiff in 1960. It
suggested the measurement of the minute precession of a gyroscope
orbiting a rotating gravitating body. Fairbank and Robert Cannon from
the School of Engineering then initiated a program to develop the
technology and attain the necessary sensitivity. The Gravity Probe B
Project, as it is known, now under the direction of Francis Everitt,
has evolved into the top-priority scientific experiment in
gravitational physics for NASA. The first space flight is anticipated
within the next few years.
Condensed Matter
Physics
Condensed-matter physics at Stanford is led by a
group of enthusiastic faculty who are breaking new ground. Robert
Laughlin shared the 1998 Nobel Prize for his explanation of the quantum
and fractional quantum Hall effects. Doug Osheroff, the 1996
co-recipient of the Nobel Prize in Physics for his discovery of
superfluid 3He, is a leading experimentalist in the area of quantum
solids and fluids and other properties of matter very near to absolute
zero. Sandy Fetter, who has made important theoretical contributions in
vortex structures found in superfluid 4He and 3He, is active in the
theory of Bose-Einstein condensates. Aharon Kapitulnik is a
low-temperature experimentalist studying high-Tc superconductors and
the metal-insulator transition (a quantum phase transition). Sebastian
Doniach is a theorist studying superconductivity and flux pinning in
superconductors as well as various biophysics problems. Shoucheng
Zhang, who applies quantum-field-theoretic techniques to
condensed-matter problems such as the fractional quantum Hall effect,
is especially noted for his invention of the “SO(5)” theory that
unifies antiferromagnetism and superconductivity, as a possible model
for high-Tc superconducting materials. Blas Cabrera performs
experiments on superconductivity such as measuring the Cooper pair mass
and studies of vortex pinning, and uses the unusual quantum effects
found in condensed matter at low temperature to develop novel detectors
for particle astrophysics. David Goldhaber-Gordon studies quantum dots,
which are artificial atoms fabricated from mesoscopic structures on
semiconducting films. Hari Manoharan uses the scanning tunneling
microscope to create atomic-scale structures on the surfaces of metals
and semiconductors. Steve Kivelson, who joined the Physics
faculty in 2004, plays a leading role in the theoretical physics of
correlated electron systems.
Other Disciplines
Finally, both theoretical and experimental
particle physics continue to thrive at Stanford. Leonard Susskind and
Savas Dimopoulos, the main authors of technicolor and supersymmetry as
extensions of the Standard Model, along with Renata Kallosh, a leading
expert on supergravity and superstring theory, form the nucleus of a
dynamic and synergistic particle-theory group that is closely linked to
our astrophysics, condensed-matter, and SLAC theorists. Stephen
Shenker, a world leader in theoretical particle physics and string
theory, is the Director of the Stanford Institute for Theoretical
Physics. In addition, Shamit Kachru and Eva Silverstein, two string
theorists, have joint appointments in the Physics Department and SLAC,
thus strengthening the already strong ties between the two entities.
On the experimental side, Stan Wojcicki will study
neutrino oscillations using a neutrino beam created at Fermilab and an
underground detector in Minnesota. Wojcicki is currently spokesperson
for the MINOS experiment, which should reveal whether or not neutrinos
actually oscillate, and if so, will be able to measure the oscillation
mode and mixing parameters. Patricia Burchat is one of the leaders of
the BABAR experiment at the B factory facility at SLAC, which explores
CP violation in the decays of B mesons. Giorgio Gratta has recently
completed an experiment searching for neutrino oscillations with the
Palo Verde reactor and is now working on experimental studies of
neutrino properties and astrophysics with the KamLAND detector in
Japan. Gratta is also active in developing new techniques in particle
detection.
In addition to research in the Physics Department
and at SLAC, graduate students in Physics have access to research
projects in Applied Physics, Electrical Engineering, Materials Science
and Engineering, and collaborative efforts with the Medical School. A
major factor in Stanford's successful history of innovation has been
the ease of collaborations across disciplinary and departmental
boundaries; this tradition continues today.
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