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MMS targets the fundamental physics that drives magnetic reconnection, energy conversion, particle acceleration, mass/energy transport, and turbulence and will continue its unique role within NASA’s Heliophysics System Observatory during the 3rd extended mission. Five sessions are planned centered around the science objectives of the 3rd MMS extended mission. Additional science sessions are available for all other science topics.
Session Topics
- Programmatic - Mission status, HQ, Senior Review results, SOC status, MOC status, EPO efforts, .....
- String-of-pearls formation - Planning for the first new formation change in the 3rd MMS Extended Mission: science, flight dynamics, burst-mode management, science region of interest.......
- Storms/Extreme events/Multi-scale - Science objective 1 (SO1) of the 3rd MMS Extended Mission is to understand the role of kinetic physics in the strongly driven magnetosphere during intense space weather events near solar maximum. By understanding how these microphysical processes couple to the larger-scale geospace environment, we aim to reach a new level of understanding of magnetospheric dynamics, and of the dynamics of a cross-scale coupled plasma system.
- Reconnection - Science objective 2 (SO2) of the 3rd MMS Extended Mission is to discover how the electron-kinetic dynamics that enable magnetic reconnection couple to the larger-scale geospace environment. Specific science questions are: What controls the effectiveness of magnetic reconnection? How is energy dissipated outside of diffusion regions? How do multiple X-lines develop and interact? What are the dominant wave-particle interactions during magnetic reconnection and their large-scale impact? How is magnetopause reconnection connected to the physics of the cusps and associated diamagnetic cavities?
- Particle acceleration - Science objective 3 (SQ3) of the 3rd MMS Extended Mission is to understand particle acceleration processes in the magnetotail and their relationship to magnetic reconnection. Specific science questions include: How does magnetotail reconnection inject energetic particles to the inner magnetosphere? What processes dominate ion energization in the magnetotail? Does reconnection energize electrons directly or via secondary processes?
- Turbulence - Science objective 4 (SO4) of the 3rd MMS Extended Mission is to understand the fundamental nature of kinetic scale turbulence, including its coupling to larger scales. Specific science questions include: How do the drivers of turbulence impact the small-scale dissipation and particle acceleration? Which turbulent processes heat and accelerate plasma?
- Shocks - Science objective 5 (SO5) of the 3rd MMS Extended Mission is to understand the role of kinetic physics in the bow shock and interplanetary shocks, including shock driven turbulence at kinetic scales and its cross-scale consequences, and large-scale impact of shock-driven reconnection.
- Other science topics
Name | Institution | Talk Title | Relevant Science Topic(s) - see numbers above |
---|---|---|---|
Neha Pathak | Laboratory for Atmospheric and Space Science, University of Colorado Boulder | Evidence of a Non-Orthogonal X-Line in Guide-Field Magnetic Reconnection | 4. Reconnection |
Jim Burch | SwRI | Parallel Electric Fields and Compressive Heating in Magnetotail Reconnection | 4. Reconnection |
Mojtaba Akhavan-Tafti | CLaSP, University of Michigan | Magnetospheric Time History in Storm-Time Magnetic Flux Dynamics | 3. Storms/Extreme events/Multi-scale |
Owen Roberts | Austrian Academy of Sciences | Case study of a magnetosheath jet | 8. Other science topics |
Gangkai Poh | NASA GSFC/CUA | Statistical Analysis of 3-second waves observed by MMS in the Earth's foreshock | 8. Other science topics |
Brandon Burkholder | NASA GSFC/UMBC | Can magnetotail reconnection occur when the solar wind is sub-alfvenic? Case study of the April 2023 Storm | 3. Storms/Extreme events/Multi-scale |
Naoki Bessho | UMCP/NASA GSFC | Island betatron acceleration in magnetic flux ropes in the Earth's bow shock | 5. Particle acceleration |
Joo Hwang | SwRI | Electron energization at a two-step dipolarziation front | 5. Particle acceleration |
Scott Boardsen/Guan Le | UMBC/GSFC | Event Study of ICW and Drift Mirror Waves observed by both MMS and Geotail while separated by a few wavelengths. | 8. |
Sohom Roy | University of Delaware | Investigating the scale-dependent conversion of turbulent energy in the magnetosheath | 6. Turbulence |
Subash Adhikari | West Virginia University | Kinetic Reconnection and Associated Turbulence: A Scale Filtering Approach | 6. Turbulence |
Marit Oieroset | UC Berkeley | Scaling of ion bulk heating produced by reconnection in the low Beta and high Alfvén speed regime of Earth’s magnetotail | 4. Reconnection |
Rachel Rice | UMCP/NASA GSFC | Comparing magnetopause boundary layers in storm time | 3. Storms |
Sanjay Chepuri | University of Iowa | Testing Adiabatic Models of Energetic Particle Acceleration at Dipolarization Fronts | 5. Particle acceleration |
Harry Arnold | JHU/APL | PIC simulations of overstretched ion scale current sheets applicable to the magnetotail | 4. Reconnection |
Steve Petrinec | Lockheed-Martin | MMS String-of-Pearls Formation: Science Regions of Interest (SROIs) | 2. String-of-Pearls |
Li-Jen Chen | NASA/GSFC | Earth's dynamic filamentary Alfven wings driven by the 2023 April CME | 3. Storms/extreme events |
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