PPPL-3202 is available in <a href="PPPL-3202.pdf">pdf</a> format.
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<b>Confinement Analysis in L-Mode of Hydrogen Isotope Experiments on TFTR</b>
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Authors:         C.W. Barnes, S.D. Scott, M.G. Bell, et al

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The effect of isotope on confinement in high-recycling, L-mode plasmas is studied
on the Tokamak Fusion Test Reactor (TFTR) by comparing hydrogen and deuterium
plasmas with the same magnetic field and similar electron densities and heating
power, with both Ohmic and deuterium-neutral-beam heating. Following a long
operational period in deuterium, nominally hydrogen plasmas were created through
hydrogen glow discharge and hydrogen gas puffing in Ohmic plasmas, which
saturated the exposed limiter surface with hydrogen and raised the H/(H+D) ratio
from 10+3% to 65+5%. Ohmic deuterium discharges obtained higher stored energy
and lower loop voltage than hydrogen discharges with similar limiter conditions.
Neutral-beam power scans were conducted in L-mode plasmas at minor radii of
50 and 80 cm, with plasma currents of 0.7 and 1.4 MA. To minimize transport
differences from the beam deposition profile and beam heating, deuterium neutral
beams were used to heat the plasmas of both isotopes. Total stored energy increased
approximately 20% from nominally hydrogen plasmas to deuterium plasmas during
auxiliary heating. Of this increase about half can be attributed to purely classical
differences in the energy content of unthermalized beam ions. Kinetic measurements
indicate a consistent but small increase in central electron temperature and total
stored electron energy in deuterium relative to hydrogen plasmas, but no change in
total ion stored energy. No significant differences in particle transport, momentum
transport, and sawtooth behavior are observed. Overall, only a small improvement
(10%) in global energy confinement time of the thermal plasma is seen between
operation in hydrogen and deuterium.
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