Reconstruction Analysis of Global Ionospheric Outflow Patterns

Michael W. Liemohn; Jörg Micha Jahn; Raluca Ilie; Natalia Y. Ganushkina; Daniel T. Welling; Heather A. Elliott; Meghan Burleigh; Kaitlin Doublestein; Stephanie A. Colon-Rodriguez; Pauline Dredger; Philip W. Valek

doi:10.1029/2023JA032238

Reconstruction Analysis of Global Ionospheric Outflow Patterns

Michael W. Liemohn, Jörg Micha Jahn, Raluca Ilie, Natalia Y. Ganushkina, Daniel T. Welling, Heather A. Elliott, Meghan Burleigh, Kaitlin Doublestein, Stephanie A. Colon-Rodriguez, Pauline Dredger, Philip W. Valek

Research output: Contribution to journal › Article › peer-review

Abstract

Ionospheric outflow supplies nearly all of the heavy ions observed within the magnetosphere, as well as a significant fraction of the proton density. While much is known about upflow and outflow energization processes, the full global pattern of outflow and its evolution is only known statistically or through numerical modeling. Because of the dominant role of heavy ions in several key physical processes, this unknown nature of the full outflow pattern leads to significant uncertainty in understanding geospace dynamics, especially surrounding storm intervals. That is, global models risk not accurately reproducing the main features of intense space storms because the amount of ionospheric outflow is poorly specified and thus magnetospheric composition and mass loading could be ill-defined. This study defines a potential mission to observe ionospheric outflow from several platforms, allowing for a reasonable and sufficient reconstruction of the full outflow pattern on an orbital cadence. An observing system simulation experiment is conducted, revealing that four well-placed satellites are sufficient for reasonably accurate outflow reconstructions. The science scope of this mission could include the following: reveal the global structure of ionospheric outflow; relate outflow patterns to geomagnetic activity level; and determine the spatial and temporal nature of outflow composition. The science objectives could be focused to be achieved with minimal instrumentation (only a low-energy ion spectrometer to obtain outflow reconstructions) or with a larger scientific scope by including contextual instrumentation.

Original language	English (US)
Article number	e2023JA032238
Journal	Journal of Geophysical Research: Space Physics
Volume	129
Issue number	5
DOIs	https://doi.org/10.1029/2023JA032238
State	Published - May 2024
Externally published	Yes

Keywords

high-latitude ionosphere
instruments and techniques
ion composition
ionosphere/magnetosphere interactions
ionospheric outflow
magnetic storms and substorms
magnetosphere-ionosphere coupling
magnetosphere/ionosphere interactions
polar cap phenomena
space mission
spaceflight hardware

ASJC Scopus subject areas

Geophysics
Space and Planetary Science

Online availability

10.1029/2023JA032238

Library availability

Discover UIUC Full Text

Cite this

@article{d37c6dc0f8964dc1ab2f7011ffdf5f2e,

title = "Reconstruction Analysis of Global Ionospheric Outflow Patterns",

abstract = "Ionospheric outflow supplies nearly all of the heavy ions observed within the magnetosphere, as well as a significant fraction of the proton density. While much is known about upflow and outflow energization processes, the full global pattern of outflow and its evolution is only known statistically or through numerical modeling. Because of the dominant role of heavy ions in several key physical processes, this unknown nature of the full outflow pattern leads to significant uncertainty in understanding geospace dynamics, especially surrounding storm intervals. That is, global models risk not accurately reproducing the main features of intense space storms because the amount of ionospheric outflow is poorly specified and thus magnetospheric composition and mass loading could be ill-defined. This study defines a potential mission to observe ionospheric outflow from several platforms, allowing for a reasonable and sufficient reconstruction of the full outflow pattern on an orbital cadence. An observing system simulation experiment is conducted, revealing that four well-placed satellites are sufficient for reasonably accurate outflow reconstructions. The science scope of this mission could include the following: reveal the global structure of ionospheric outflow; relate outflow patterns to geomagnetic activity level; and determine the spatial and temporal nature of outflow composition. The science objectives could be focused to be achieved with minimal instrumentation (only a low-energy ion spectrometer to obtain outflow reconstructions) or with a larger scientific scope by including contextual instrumentation.",

keywords = "high-latitude ionosphere, instruments and techniques, ion composition, ionosphere/magnetosphere interactions, ionospheric outflow, magnetic storms and substorms, magnetosphere-ionosphere coupling, magnetosphere/ionosphere interactions, polar cap phenomena, space mission, spaceflight hardware",

author = "Liemohn, {Michael W.} and Jahn, {J{\"o}rg Micha} and Raluca Ilie and Ganushkina, {Natalia Y.} and Welling, {Daniel T.} and Elliott, {Heather A.} and Meghan Burleigh and Kaitlin Doublestein and Colon-Rodriguez, {Stephanie A.} and Pauline Dredger and Valek, {Philip W.}",

note = "The authors thank the University of Michigan and Southwest Research Institute for support of this project. The authors would like to thank the University of Michigan for its financial support, Southwest Research Institute for its financial support, and the US government, in particular research grants from NASA (specifically, Grants 80NSSC19K0077, 80NSSC21K1127, and 80NSSC21K1405) and NSF (specifically, Grant AGS\u20101414517). MB was supported by the Office of Naval Research. All authors listed have made a substantial, direct, and intellectual contribution to the work and approved it for publication. The simulations were conducted by DTW and analyzed by DTW and MWL. An undergraduate student, Joshua Adam, also contributed to the plots and calculations. Figures 1 and 3 were created by the scientific graphics group at Southwest Research Institute; the authors greatly appreciate their help with these and other illustrations.",

year = "2024",

month = may,

doi = "10.1029/2023JA032238",

language = "English (US)",

volume = "129",

journal = "Journal of Geophysical Research: Space Physics",

issn = "2169-9380",

publisher = "Wiley-Blackwell",

number = "5",

}

TY - JOUR

T1 - Reconstruction Analysis of Global Ionospheric Outflow Patterns

AU - Liemohn, Michael W.

AU - Jahn, Jörg Micha

AU - Ilie, Raluca

AU - Ganushkina, Natalia Y.

AU - Welling, Daniel T.

AU - Elliott, Heather A.

AU - Burleigh, Meghan

AU - Doublestein, Kaitlin

AU - Colon-Rodriguez, Stephanie A.

AU - Dredger, Pauline

AU - Valek, Philip W.

N1 - The authors thank the University of Michigan and Southwest Research Institute for support of this project. The authors would like to thank the University of Michigan for its financial support, Southwest Research Institute for its financial support, and the US government, in particular research grants from NASA (specifically, Grants 80NSSC19K0077, 80NSSC21K1127, and 80NSSC21K1405) and NSF (specifically, Grant AGS\u20101414517). MB was supported by the Office of Naval Research. All authors listed have made a substantial, direct, and intellectual contribution to the work and approved it for publication. The simulations were conducted by DTW and analyzed by DTW and MWL. An undergraduate student, Joshua Adam, also contributed to the plots and calculations. Figures 1 and 3 were created by the scientific graphics group at Southwest Research Institute; the authors greatly appreciate their help with these and other illustrations.

PY - 2024/5

Y1 - 2024/5

N2 - Ionospheric outflow supplies nearly all of the heavy ions observed within the magnetosphere, as well as a significant fraction of the proton density. While much is known about upflow and outflow energization processes, the full global pattern of outflow and its evolution is only known statistically or through numerical modeling. Because of the dominant role of heavy ions in several key physical processes, this unknown nature of the full outflow pattern leads to significant uncertainty in understanding geospace dynamics, especially surrounding storm intervals. That is, global models risk not accurately reproducing the main features of intense space storms because the amount of ionospheric outflow is poorly specified and thus magnetospheric composition and mass loading could be ill-defined. This study defines a potential mission to observe ionospheric outflow from several platforms, allowing for a reasonable and sufficient reconstruction of the full outflow pattern on an orbital cadence. An observing system simulation experiment is conducted, revealing that four well-placed satellites are sufficient for reasonably accurate outflow reconstructions. The science scope of this mission could include the following: reveal the global structure of ionospheric outflow; relate outflow patterns to geomagnetic activity level; and determine the spatial and temporal nature of outflow composition. The science objectives could be focused to be achieved with minimal instrumentation (only a low-energy ion spectrometer to obtain outflow reconstructions) or with a larger scientific scope by including contextual instrumentation.

AB - Ionospheric outflow supplies nearly all of the heavy ions observed within the magnetosphere, as well as a significant fraction of the proton density. While much is known about upflow and outflow energization processes, the full global pattern of outflow and its evolution is only known statistically or through numerical modeling. Because of the dominant role of heavy ions in several key physical processes, this unknown nature of the full outflow pattern leads to significant uncertainty in understanding geospace dynamics, especially surrounding storm intervals. That is, global models risk not accurately reproducing the main features of intense space storms because the amount of ionospheric outflow is poorly specified and thus magnetospheric composition and mass loading could be ill-defined. This study defines a potential mission to observe ionospheric outflow from several platforms, allowing for a reasonable and sufficient reconstruction of the full outflow pattern on an orbital cadence. An observing system simulation experiment is conducted, revealing that four well-placed satellites are sufficient for reasonably accurate outflow reconstructions. The science scope of this mission could include the following: reveal the global structure of ionospheric outflow; relate outflow patterns to geomagnetic activity level; and determine the spatial and temporal nature of outflow composition. The science objectives could be focused to be achieved with minimal instrumentation (only a low-energy ion spectrometer to obtain outflow reconstructions) or with a larger scientific scope by including contextual instrumentation.

KW - high-latitude ionosphere

KW - instruments and techniques

KW - ion composition

KW - ionosphere/magnetosphere interactions

KW - ionospheric outflow

KW - magnetic storms and substorms

KW - magnetosphere-ionosphere coupling

KW - magnetosphere/ionosphere interactions

KW - polar cap phenomena

KW - space mission

KW - spaceflight hardware

UR - http://www.scopus.com/inward/record.url?scp=85192850405&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85192850405&partnerID=8YFLogxK

U2 - 10.1029/2023JA032238

DO - 10.1029/2023JA032238

M3 - Article

AN - SCOPUS:85192850405

SN - 2169-9380

VL - 129

JO - Journal of Geophysical Research: Space Physics

JF - Journal of Geophysical Research: Space Physics

IS - 5

M1 - e2023JA032238

ER -

Reconstruction Analysis of Global Ionospheric Outflow Patterns

Abstract

Keywords

ASJC Scopus subject areas

Online availability

Library availability

Related links

Fingerprint

Cite this