Journal
NATURE PHYSICS
Volume 6, Issue 3, Pages 207-212Publisher
NATURE PUBLISHING GROUP
DOI: 10.1038/NPHYS1510
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Funding
- Columbia University
- Massachusetts Institute of Technology
- USDOE Office of Fusion Energy Sciences [DE-FG02-98ER54458, DE-FG02-98ER54459]
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The rearrangement of plasma as a result of turbulence is among the most important processes that occur in planetary magnetospheres and in experiments used for fusion energy research. Remarkably, fluctuations that occur in active magnetospheres drive particles inward and create centrally peaked profiles. Until now, the strong peaking seen in space has been undetectable in the laboratory because the loss of particles along the magnetic field is faster than the net driven flow across the magnetic field. Here, we report the first laboratory measurements in which a strong superconducting magnet is levitated and used to confine high-temperature plasma in a configuration that resembles planetary magnetospheres. Levitation eliminates field-aligned particle loss, and the central plasma density increases markedly. The build-up of density characterizes a sustained turbulent pinch and is equal to the rate predicted from measured electric-field fluctuations. Our observations show that dynamic principles describing magnetospheric plasma are relevant to plasma confined by a levitated dipole.
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