Difference between revisions of "FG: Magnetospheric Sources of Particle Precipitation and Their Role on Electrodynamic Coupling of Magnetosphere-Ionosphere-Thermosphere Systems"

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== 2022 GEM Workshop Agenda ==
 
== 2022 GEM Workshop Agenda ==
  
=== MPEC Stand-alone session on Monday June 20, 2022, 13:30-15:00 HDT, at Bluefin ===
+
=== MPEC Stand-alone session on Monday, June 20, 2022, 13:30-15:00 HDT, at Bluefin ===
 
This session will focus on observational studies to address the  
 
This session will focus on observational studies to address the  
  
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=== MPEC Stand-alone session on Tuesday June 21, 2022, 10:30-12:00 HDT, at Alohilani II ===
+
=== MPEC Stand-alone session on Tuesday, June 21, 2022, 10:30-12:00 HDT, at Alohilani II ===
 
This session will focus on numerical studies to address the  
 
This session will focus on numerical studies to address the  
  
1. Bill Lotko, TBD <br>
+
1. Bill Lotko, TBD (Modelling of Magnetospheric Particle Precipitation) <br>
 
2. Eftyhia Zesta, "Role of Ion Precipitation in M-I Coupling and Electron Upflow" <br>
 
2. Eftyhia Zesta, "Role of Ion Precipitation in M-I Coupling and Electron Upflow" <br>
 
3. Yu Lin, "Cusp Ion Precipitation Associated with Magnetopause Reconnection Viewed from Global Hybrid Simulation" <br>
 
3. Yu Lin, "Cusp Ion Precipitation Associated with Magnetopause Reconnection Viewed from Global Hybrid Simulation" <br>
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6. Shanshan Bao, "Gray-box Modeling of Particle Scattering and Auroral Precipitation" <br>
 
6. Shanshan Bao, "Gray-box Modeling of Particle Scattering and Auroral Precipitation" <br>
 
7. Zihan Wang, "COMPASS: A New COnductance Model Based on PFISR And SWARM Satellite Observations" <br>
 
7. Zihan Wang, "COMPASS: A New COnductance Model Based on PFISR And SWARM Satellite Observations" <br>
 +
 +
=== MPEC-SCIMM joint session on Wednesday, June 22, 2022, 13:30-15:00 HDT, at Alohilani II ===
 +
 +
1. Raluca Ilie, "Ionospheric Feedback to the Magnetosphere" <br>
 +
2. Michael Hartinger, "ULF Wave Modulation of Total Electron Content" <br>
 +
3. Mei-Ching Fok, TBD (Particle precipitation with the CIMI model) <br>
 +
4. Yongliang Zhang, "Ring Current Aurora" <br>
 +
5. Qianli Ma, "Electron Precipitation and Ionospheric Density Enhancements due to Hiss" <br>
 +
6. Dillon Gillespie, "Global Statistics of Diffuse Electron Aurora and Ionospheric Conductance Directly Derived from Whistler-mode Chorus Waves" <br>
 +
7. Dong Lin, "Origin of the Dawnside SAPS During Major Geomagnetic Storms" <br>
 +
 +
=== MPEC-SCIMM joint session on Thursday, June 23, 2022, 13:30-15:00 HDT, at Alohilani II ===
 +
 +
1. Emma Spanswick, "Proposed Upgrades to UCalgary & UAlberta Ground Arrays in Advance of GDC" <br>
 +
2. Jeremiah Johnson, "Understanding Auroral Morphology Through Self-Supervised Machine Learning" <br>
 +
3. Margaret Chen, "Effects of Diffuse Auroral Precipitation on Ionospheric Conductivity and Joule Heating During Storms: Simulation and Data Comparisons" <br>
 +
4. Agnit Mukhopadhyay, "Global Driving of Auroral Precipitation" <br>
 +
5. Eftyhia Zesta, "Impact of the Precipitation Energy Distribution on the I-T system" <br>

Revision as of 12:29, 16 June 2022

The particles precipitating from the magnetosphere play an important role in the determination and modelling of ionospheric electrodynamics, especially conductance which modulates the magnetosphere’s response to the solar wind. Precipitation of magnetospheric particles and their energy deposition in the Earth’s upper atmosphere depend on a number of parameters including, but not limited to, their magnetospheric origin, energy range, flux, auroral display, spatiotemporal scale, etc. As a result, the ionospheric conductance can be modified in various ways further affecting the plasma convection, field-aligned (FAC) and ionospheric currents, and ionospheric/thermospheric temperature and densities. Therefore, understanding the properties of different sources of magnetospheric precipitation and their relative roles in the electrodynamic coupling of M-I across a broad range of spatiotemporal scales is crucial for improving predictive modelling capabilities. This broad topic necessitates the existence of a designated GEM focus group to achieve a community-wide collaboration.

🪑 Focus Group Chairs

🗓 Focus Group Goals
To advance the physical knowledge and improve the numerical modelling of
- The magnetospheric particle precipitation (precipitation mechanism and characteristics, magnetospheric origin, auroral forms).
- The effects of particle precipitation on the ionospheric electrodynamics, with an emphasis on the ionospheric conductance.
- Response of the I-T system to precipitation and its feedback to the Magnetosphere.

🤝 Get Involved in MPEC FG
Please sign-up to our MPEC e-mail list to learn more about our FG activities and opportunities to participate at a greater capacity: https://forms.gle/BrsYo6LCewiysUij6.

GEM Workshops

2022 GEM Workshop Agenda

MPEC Stand-alone session on Monday, June 20, 2022, 13:30-15:00 HDT, at Bluefin

This session will focus on observational studies to address the

1. Allison Jaynes, "Rocket Missions and the Energetic Content of Pulsating Aurora"
2. Riley Troyer, "Substorm Activity as a Driver of Energetic Pulsating Aurora"
3. Mykhaylo Shumko, "The Association of Relativistic Electron Microbursts With the Aurora"
4. Jone Peter Reistad, "Origins of keV Electron Precipitation in the Summer Hemisphere Polar Cap: On the Structure and Dynamics of High Latitude Dayside Aurora"
5. Christine Gabrielse, "Estimating Precipitating Energy Flux, Average Energy, and Hall Auroral Conductance in 2D From THEMIS All-Sky-Imagers With Focus on Mesoscales"
6. Jiang Liu, "Embedded R1 and R2 Currents: a Source of Intense Precipitation, and Their Preferred Condition"
7. Harneet Sangha, "An Analysis of Region 2 Field-Aligned Current Bifurcations"


MPEC Stand-alone session on Tuesday, June 21, 2022, 10:30-12:00 HDT, at Alohilani II

This session will focus on numerical studies to address the

1. Bill Lotko, TBD (Modelling of Magnetospheric Particle Precipitation)
2. Eftyhia Zesta, "Role of Ion Precipitation in M-I Coupling and Electron Upflow"
3. Yu Lin, "Cusp Ion Precipitation Associated with Magnetopause Reconnection Viewed from Global Hybrid Simulation"
4. Yann Pfau-Kempf, "Magnetosphere-Ionosphere Coupling in Vlasiator"
5. Maxime Grandin, "First 3D Results with Vlasiator on Auroral Proton Precipitation During Southward Interplanetary Magnetic Field Driving"
6. Shanshan Bao, "Gray-box Modeling of Particle Scattering and Auroral Precipitation"
7. Zihan Wang, "COMPASS: A New COnductance Model Based on PFISR And SWARM Satellite Observations"

MPEC-SCIMM joint session on Wednesday, June 22, 2022, 13:30-15:00 HDT, at Alohilani II

1. Raluca Ilie, "Ionospheric Feedback to the Magnetosphere"
2. Michael Hartinger, "ULF Wave Modulation of Total Electron Content"
3. Mei-Ching Fok, TBD (Particle precipitation with the CIMI model)
4. Yongliang Zhang, "Ring Current Aurora"
5. Qianli Ma, "Electron Precipitation and Ionospheric Density Enhancements due to Hiss"
6. Dillon Gillespie, "Global Statistics of Diffuse Electron Aurora and Ionospheric Conductance Directly Derived from Whistler-mode Chorus Waves"
7. Dong Lin, "Origin of the Dawnside SAPS During Major Geomagnetic Storms"

MPEC-SCIMM joint session on Thursday, June 23, 2022, 13:30-15:00 HDT, at Alohilani II

1. Emma Spanswick, "Proposed Upgrades to UCalgary & UAlberta Ground Arrays in Advance of GDC"
2. Jeremiah Johnson, "Understanding Auroral Morphology Through Self-Supervised Machine Learning"
3. Margaret Chen, "Effects of Diffuse Auroral Precipitation on Ionospheric Conductivity and Joule Heating During Storms: Simulation and Data Comparisons"
4. Agnit Mukhopadhyay, "Global Driving of Auroral Precipitation"
5. Eftyhia Zesta, "Impact of the Precipitation Energy Distribution on the I-T system"