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In
This Issue:
 NSF
Early Career Awards
Grads
and Frosh
Professor
Morton Klein
Teaching
Prizes Given
Young
Alums Needed
Alumni
Briefs
Homecoming
2001
School Mourns
WTC Victims
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FEATURE
STORY
Gerald
Navratil, left, professor of applied physics, and Columbia research
scientist Andrea Garofalo stand in front of a cross-section model
of the DIII-D Tokamak fusion energy experiment at General Atomics
in San Diego.
The heat of the summer months was no match for the heat and pressure
produced this summer at General Atomics’ DIII-D National
Fusion Facility in San Diego. In experiments that built on research
done on the HBT-EP fusion device at the School two years ago,
Columbia physicists in California have increased by a factor of
two the threshold pressure for stable confinement of hot, ionized
gases by strong toroidal magnetic force fields.
“We are able to take Columbia’s work on a small level
and immediately apply it to the largest experiments in our field,”
said Gerald Navratil, professor of applied physics, who, with
Columbia research scientist Andrea Garofalo ’98 (Ph.D.) was
responsible for the new developments at General Atomics. “We
have the best of both worlds—experimenting at the university
level and then applying the results on the very largest facilities
in the country.”
Navratil and Michael Mauel, chair of the Department of Applied
Physics and Applied Mathematics, are among the nation’s top
scientists leading fusion science programs at General Atomics,
the Princeton Plasma Physics Laboratory and MIT’s Plasma
Science and Fusion Center. “This is a national effort,”
said Mauel. “We are all working together to offer a very
exciting research environment for students while also working
to create a practical fusion energy source for the future.”
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Students
work on the Tokamok reactor that was responsible for groundbreaking
work in increasing threshold pressure of gases. |
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With temperatures approaching 200 million degrees Celsius, fusion
fuel, or plasma, must be suspended by strong magnetic fields within
large toroidal vacuum chambers. During the past decade, scientists
discovered that when the ring-like plasma spins within the containment
device, less power must be injected into the plasma to maintain
its high temperature and pressure. Unfortunately, as the pressure
increases, the plasma becomes unstable and makes contact with
the metal wall of the vacuum chamber. When this happens, the plasma
cools immediately and must be restarted.
The experiments led by Mauel and Navratil on the HBT-EP device
at Columbia were the first to demonstrate that, by correcting
imperfections in the magnetic field, it is possible to prevent
the growth of these plasma instabilities. In the new experiments
at DIII-D, similar techniques were able to maintain the “spin”
of the plasma by combining passive stabilizing effects of the
metal wall and active control coils using a sophisticated feedback
control loop. Sensors installed on the edge of the confinement
chamber detect distortions in the plasma and immediately signal
the magnetic coils to provide a correction that smoothes out the
bumps and kinks. Dr. Garofalo reported this pioneering work in
early November in an invited paper at the American Physical Society’s
Plasma Physics Meeting.
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