Time and Space Resolved Optical Measurements of Reconnection in PHASMA
POSTER
Abstract
In previous studies, the complex dynamical behavior of kinking 3D flux
ropes have been observed and studied within the PHASMA (PHAse Space
MApping) facility. For the first time, temporally and spatially resolved
measurements of flux rope dynamics within PHASMA are obtained through
measurements of emitted light intensity using photodiode arrays,
allowing for the direct observation of flux rope evolution, movement and
reconnection in 3 dimensions. These optical measurements are referenced
against magnetic field data obtained from B-dot probes, potentially
offering a non-perturbative, high dynamic range alternative to
conventional field mapping techniques for detecting the onset of
magnetic reconnection. Incorporation of the photodiode observations into
a real-time predictive model may also enable the development of a
predictive trigger for synchronized magnetic reconnection measurements.
ropes have been observed and studied within the PHASMA (PHAse Space
MApping) facility. For the first time, temporally and spatially resolved
measurements of flux rope dynamics within PHASMA are obtained through
measurements of emitted light intensity using photodiode arrays,
allowing for the direct observation of flux rope evolution, movement and
reconnection in 3 dimensions. These optical measurements are referenced
against magnetic field data obtained from B-dot probes, potentially
offering a non-perturbative, high dynamic range alternative to
conventional field mapping techniques for detecting the onset of
magnetic reconnection. Incorporation of the photodiode observations into
a real-time predictive model may also enable the development of a
predictive trigger for synchronized magnetic reconnection measurements.
Presenters
-
Thomas Rood
West Virginia University
Authors
-
Thomas Rood
West Virginia University
-
Peiyun Shi
Department of Physics and Astronomy and Center for KINETIC Plasma Physics, West Virginia University, Morgantown, WV 26506, USA, West Virginia University
-
Gabriela Himmele
West Virginia University
-
Earl Scime
West Virginia University, Department of Physics and Astronomy and Center for KINETIC Plasma Physics, West Virginia University, Morgantown, WV 26506, USA