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Energy Partition at Collisionless Supercritical Quasi-Perpendicular Shocks

Energy Partition at Collisionless Supercritical Quasi-Perpendicular Shocks
Energy Partition at Collisionless Supercritical Quasi-Perpendicular Shocks

Collisionless shocks in astrophysical plasmas are important thermalizers, converting some of the incident flow energy into thermal energy, and non-thermalizers, partitioning that energy in unequal ways to different particle species, subpopulations thereof, and field components. This partition problem, or equivalently the shock equation of state, lies at the heart of shock physics. Here, we employ systematically a framework to capture all the incident and downstream energy fluxes at two example traversals of the Earth's bow shock by the Magnetospheric Multiscale Mission. Here and traditionally, such data has to be augmented by information from other spacecraft, for example, to provide more accurate measurements of the cold solar wind beam. With some care and fortuitous choices, the total energy flux is conserved, including instantaneous measurements through the shock layer. The dominant incident proton ram energy is converted primarily into downstream proton enthalpy flux, the majority of which is actually carried by a small fraction of suprathermal protons. Fluctuations include both real and instrumental effects. Separating these, resolving the solar wind beam, and other considerations point the way to a dedicated mission to solve this energy partition problem across a full range of plasma and shock conditions.

collisionless shocks, energy partition
2169-9380
Schwartz, Steven J.
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Goodrich, Katherine A.
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Wilson, Lynn B.
334374c5-a025-4333-b7a4-d9584e9e36b1
Turner, Drew L.
cd9e03bf-0fe2-4abd-9a38-4e4a6beec89c
Trattner, Karlheinz J.
93c56ffe-958a-41c3-821d-550a0883e366
Kucharek, Harald
26be3c68-a369-4653-b8ce-ed464946bc42
Gingell, Imogen
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Fuselier, Stephen A.
8e5124fa-41eb-4239-948e-3111c92b525a
Cohen, Ian J.
f8be6dbe-eb7a-429e-a5c9-005447e5d27b
Madanian, Hadi
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Ergun, Robert E.
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Gershman, Daniel J.
00afda5d-e397-4629-b978-12058b1f7c72
Strangeway, Robert J.
2fd4cc7c-d923-448d-babf-ce95399ed494
Schwartz, Steven J.
6e89ea4b-98a3-4a7d-900e-63dd9a64cd4c
Goodrich, Katherine A.
f69d2b71-2695-4fa4-8ddf-38491dd98696
Wilson, Lynn B.
334374c5-a025-4333-b7a4-d9584e9e36b1
Turner, Drew L.
cd9e03bf-0fe2-4abd-9a38-4e4a6beec89c
Trattner, Karlheinz J.
93c56ffe-958a-41c3-821d-550a0883e366
Kucharek, Harald
26be3c68-a369-4653-b8ce-ed464946bc42
Gingell, Imogen
ba7b8113-3833-40d8-a879-aab3f987455d
Fuselier, Stephen A.
8e5124fa-41eb-4239-948e-3111c92b525a
Cohen, Ian J.
f8be6dbe-eb7a-429e-a5c9-005447e5d27b
Madanian, Hadi
5ccd860a-5114-4f20-86f0-f9330bdcf06c
Ergun, Robert E.
29d9ee4e-c45f-4e74-b478-3131183c6602
Gershman, Daniel J.
00afda5d-e397-4629-b978-12058b1f7c72
Strangeway, Robert J.
2fd4cc7c-d923-448d-babf-ce95399ed494

Schwartz, Steven J., Goodrich, Katherine A., Wilson, Lynn B., Turner, Drew L., Trattner, Karlheinz J., Kucharek, Harald, Gingell, Imogen, Fuselier, Stephen A., Cohen, Ian J., Madanian, Hadi, Ergun, Robert E., Gershman, Daniel J. and Strangeway, Robert J. (2022) Energy Partition at Collisionless Supercritical Quasi-Perpendicular Shocks. Journal of Geophysical Research: Space Physics, 127 (10), [e2022JA030637]. (doi:10.1029/2022JA030637).

Record type: Article

Abstract

Collisionless shocks in astrophysical plasmas are important thermalizers, converting some of the incident flow energy into thermal energy, and non-thermalizers, partitioning that energy in unequal ways to different particle species, subpopulations thereof, and field components. This partition problem, or equivalently the shock equation of state, lies at the heart of shock physics. Here, we employ systematically a framework to capture all the incident and downstream energy fluxes at two example traversals of the Earth's bow shock by the Magnetospheric Multiscale Mission. Here and traditionally, such data has to be augmented by information from other spacecraft, for example, to provide more accurate measurements of the cold solar wind beam. With some care and fortuitous choices, the total energy flux is conserved, including instantaneous measurements through the shock layer. The dominant incident proton ram energy is converted primarily into downstream proton enthalpy flux, the majority of which is actually carried by a small fraction of suprathermal protons. Fluctuations include both real and instrumental effects. Separating these, resolving the solar wind beam, and other considerations point the way to a dedicated mission to solve this energy partition problem across a full range of plasma and shock conditions.

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More information

Accepted/In Press date: 13 September 2022
e-pub ahead of print date: 13 October 2022
Additional Information: Funding Information: Some of the work was supported by the International Space Science Institute's International Teams programme (“Resolving the Microphysics of Collisionless Shock Waves” led by L.B. Wilson III) and the Geospace Environment Modeling Focus Group “Particle Heating and Thermalization in Collisionless Shocks in the Magnetospheric multiscale mission (MMS) Era” led by L.B. Wilson III. This work was supported by NASA Awards 80NSSC19K0849 and 80NSSC20K0688, together with NASA MMS contracts to the instrument teams. Publisher Copyright: © 2022. American Geophysical Union. All Rights Reserved.
Keywords: collisionless shocks, energy partition
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Identifiers

Local EPrints ID: 477272
URI: http://eprints.soton.ac.uk/id/eprint/477272
DOI: doi:10.1029/2022JA030637
ISSN: 2169-9380
PURE UUID: bb78ae17-913b-4987-b7fa-fac5a9799492
ORCID for Imogen Gingell: ORCID iD orcid.org/0000-0003-2218-1909

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Date deposited: 01 Jun 2023 17:07
Last modified: 18 Mar 2024 03:55

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Contributors

Author: Steven J. Schwartz
Author: Katherine A. Goodrich
Author: Lynn B. Wilson
Author: Drew L. Turner
Author: Karlheinz J. Trattner
Author: Harald Kucharek
Author: Imogen Gingell ORCID iD
Author: Stephen A. Fuselier
Author: Ian J. Cohen
Author: Hadi Madanian
Author: Robert E. Ergun
Author: Daniel J. Gershman
Author: Robert J. Strangeway

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