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Evaluating the deHoffmann-Teller cross-shock potential at real collisionless shocks

Evaluating the deHoffmann-Teller cross-shock potential at real collisionless shocks
Evaluating the deHoffmann-Teller cross-shock potential at real collisionless shocks
Shock waves are common in the heliosphere and beyond. The collisionless nature of most astrophysical plasmas allows for the energy processed by shocks to be partitioned amongst particle sub-populations and electromagnetic fields via physical mechanisms that are not well understood. The electrostatic potential across such shocks is frame dependent. In a frame where the incident bulk velocity is parallel to the magnetic field, the deHoffmann-Teller frame, the potential is linked directly to the ambipolar electric field established by the electron pressure gradient. Thus measuring and understanding this potential solves the electron partition problem, and gives insight into other competing shock processes. Integrating measured electric fields in space is problematic since the measurements can have offsets that change with plasma conditions. The offsets, once integrated, can be as large or larger than the shock potential. Here we exploit the high-quality field and plasma measurements from NASA's Magnetospheric Multiscale mission to attempt this calculation. We investigate recent adaptations of the deHoffmann-Teller frame transformation to include time variability, and conclude that in practice these face difficulties inherent in the 3D time-dependent nature of real shocks by comparison to 1D simulations. Potential estimates based on electron fluid and kinetic analyses provide the most robust measures of the deHoffmann-Teller potential, but with some care direct integration of the electric fields can be made to agree. These results suggest that it will be difficult to independently assess the role of other processes, such as scattering by shock turbulence, in accounting for the electron heating.
2169-9380
Schwartz, Steven J.
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Ergun, Robert
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Kucharek, Harald
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Wilson III, Lynn
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Chen, Li-Jen
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Goodrich, Katherine
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Turner, Drew
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Gingell, Imogen
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Madanian, Hadi
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Gershman, Daniel
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Strangeway, Robert
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Schwartz, Steven J.
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Ergun, Robert
a1057c29-5201-4c8e-8b3a-508357121cb6
Kucharek, Harald
26be3c68-a369-4653-b8ce-ed464946bc42
Wilson III, Lynn
20729882-b6ad-47a8-a9f1-fbd50544d700
Chen, Li-Jen
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Goodrich, Katherine
bc8947e4-01f2-4caf-b359-f08ea5872681
Turner, Drew
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Gingell, Imogen
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Madanian, Hadi
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Gershman, Daniel
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Strangeway, Robert
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Schwartz, Steven J., Ergun, Robert, Kucharek, Harald, Wilson III, Lynn, Chen, Li-Jen, Goodrich, Katherine, Turner, Drew, Gingell, Imogen, Madanian, Hadi, Gershman, Daniel and Strangeway, Robert (2021) Evaluating the deHoffmann-Teller cross-shock potential at real collisionless shocks. Journal of Geophysical Research: Space Physics, 126 (8), [e2021JA029295]. (doi:10.1029/2021JA029295).

Record type: Article

Abstract

Shock waves are common in the heliosphere and beyond. The collisionless nature of most astrophysical plasmas allows for the energy processed by shocks to be partitioned amongst particle sub-populations and electromagnetic fields via physical mechanisms that are not well understood. The electrostatic potential across such shocks is frame dependent. In a frame where the incident bulk velocity is parallel to the magnetic field, the deHoffmann-Teller frame, the potential is linked directly to the ambipolar electric field established by the electron pressure gradient. Thus measuring and understanding this potential solves the electron partition problem, and gives insight into other competing shock processes. Integrating measured electric fields in space is problematic since the measurements can have offsets that change with plasma conditions. The offsets, once integrated, can be as large or larger than the shock potential. Here we exploit the high-quality field and plasma measurements from NASA's Magnetospheric Multiscale mission to attempt this calculation. We investigate recent adaptations of the deHoffmann-Teller frame transformation to include time variability, and conclude that in practice these face difficulties inherent in the 3D time-dependent nature of real shocks by comparison to 1D simulations. Potential estimates based on electron fluid and kinetic analyses provide the most robust measures of the deHoffmann-Teller potential, but with some care direct integration of the electric fields can be made to agree. These results suggest that it will be difficult to independently assess the role of other processes, such as scattering by shock turbulence, in accounting for the electron heating.

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More information

Accepted/In Press date: 2 July 2021
e-pub ahead of print date: 15 July 2021
Published date: 1 August 2021

Identifiers

Local EPrints ID: 485389
URI: http://eprints.soton.ac.uk/id/eprint/485389
ISSN: 2169-9380
PURE UUID: 8664859b-0d70-4777-9b8f-6a8a885bd804
ORCID for Imogen Gingell: ORCID iD orcid.org/0000-0003-2218-1909

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Date deposited: 05 Dec 2023 17:48
Last modified: 17 Mar 2024 03:59

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Contributors

Author: Steven J. Schwartz
Author: Robert Ergun
Author: Harald Kucharek
Author: Lynn Wilson III
Author: Li-Jen Chen
Author: Katherine Goodrich
Author: Drew Turner
Author: Imogen Gingell ORCID iD
Author: Hadi Madanian
Author: Daniel Gershman
Author: Robert Strangeway

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