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| Type Categories -- Choose One: |
| 1. Theory/Computational |
| 2. Experimantal/Observational |
| 3. Combined/General |
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| 1.00 Fundamental Plasma Physics |
| 1.01 Advanced diagnostics and measurement innovation |
| 1.02 Analytical and computational techniques |
| 1.03 Machine learning and data science techniques in fundamental plasma physics |
| 1.04 Pure-ion and pure-electron plasma |
| 1.05 Anti-matter plasma |
| 1.06 Partially ionized and neutral-dominated plasma |
| 1.07 Strongly coupled plasma |
| 1.08 Waves, oscillations, and instabilities |
| 1.09 Turbulence and transport |
| 1.10 Magnetic reconnection |
| 1.11 Dynamics, complexity, and self-organization |
| 1.12 Elementary and atomic processes |
| 1.13 Dusty plasma and multiphase media |
| 1.14 Plasma sheath |
| 1.15 Shock wave and discontinuity |
| 1.16 Plasma production, sources, and heating |
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| 2.00 Space plasma (within heliosphere) |
| 2.01 Measurement, diagnostic techniques, and space missions |
| 2.02 Advanced diagnostics and measurement innovation |
| 2.03 Analytical and computational techniques |
| 2.04 Machine learning and data science techniques in space plasmas |
| 2.05 Planetary atmospheres and ionospheres |
| 2.06 Planetary magnetospheres |
| 2.07 Solar physics |
| 2.08 Inner Heliosphere |
| 2.09 Outer Heliosphere |
| 2.10 Turbulence and instabilities in space plasmas |
| 2.11 Shocks, magnetic reconnection, and particle acceleration in space plasmas |
| |
| 3.00 Astrophysical plasma (beyond heliosphere) |
| 3.01 Advanced diagnostics and measurement innovation |
| 3.02 Analytical and Computational Techniques in Plasma Astrophysics |
| 3.03 Machine learning and data science techniques in astrophysical plasmas |
| 3.04 Laboratory Plasma Astrophysics |
| 3.05 Interstellar and Intergalactic Medium |
| 3.06 Stars, Stellar Atmospheres, and Stellar Winds |
| 3.07 Accretion Flows, Magnetospheres, and Outflows of Compact Objects |
| 3.08 Cosmic Explosions, Compact-Object Mergers, and Multi-Messenger Astrophysics |
| 3.09 Cosmic ray acceleration and propagation |
| 3.10 Astrophysical turbulence and dynamos |
| 3.11 Astrophysical shocks, magnetic reconnection, and nonthermal particle acceleration |
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| 4.00 Low-temperature plasma science, engineering, technology, and applications |
| 4.01 Advanced diagnostics and measurement innovation |
| 4.02 Analytical and computational techniques |
| 4.03 Machine learning and data science techniques in low temperature plasma science |
| 4.04 Sustainability, catalysis, and combustion |
| 4.05 Processing and synthesis of materials |
| 4.06 Plasma propulsion |
| 4.07 Health, medicine, and bio-agent destruction |
| 4.08 Generation, stability, and control |
| 4.09 Plasma-surface interactions and interfacial plasmas |
| 4.10 Thermal plasmas |
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| 5.00 Particle acceleration, beams and relativistic plasmas |
| 5.01 Advanced diagnostics and measurement innovation |
| 5.02 Analytical and computational techniques |
| 5.03 Machine learning and data science techniques in plasma acceleration, beams and relativistic plamas |
| 5.04 Relativistic high-energy-density physics |
| 5.05 Beam-plasma wakefield accelerators |
| 5.06 Laser-plasma wakefield or direct laser accelerators |
| 5.07 Laser-plasma ion accelerators |
| 5.08 Intense laser-driven x-ray sources |
| 5.09 Coherent radiation or secondary particle sources |
| 5.10 High field physics |
| |
| 6.00 Magnetic confinement |
| 6.01 Advanced diagnostics and measurement innovation |
| 6.02 Analytical and computational techniques |
| 6.03 Machine learning and data science techniques in magnetically confined plasmas |
| 6.04 Research in support of ITER burning plasma physics |
| 6.05 Long pulse and steady-state tokamak physics |
| 6.06 Magnetohydrodynamics and stability |
| 6.07 Heating and current drive |
| 6.08 Turbulence and transport |
| 6.09 Energetic particles |
| 6.10 Disruptions and runaway electrons: modeling, avoidance, detection and mitigation |
| 6.11 Particle and power handling, divertor physics and plasma-material interactions |
| 6.12 Edge and pedestal physics |
| 6.13 Active control |
| 6.14 Conventional tokamaks: DIII-D, JET, TCV, AUG, HL-2A |
| 6.15 Superconducting tokamaks: WEST, EAST, KSTAR |
| 6.16 High field tokamaks: SPARC, C-Mod and others |
| 6.17 Low-aspect ratio tokamaks: PEGASUS, NSTX-U and MAST-U |
| 6.18 Other tokamaks: HBT-EP, J-TEXT, QUEST |
| 6.19 Stellarators and helical systems: W7-X, LHD, HSX CTH and others |
| 6.20 Magnetic mirrors and related systems |
| 6.21 Self-organized configurations: FRCs, RFPs, Spheromak, Pinches |
| 6.22 Whole device modeling |
| 6.23 Reactor technologies: measurements and diagnostics |
| 6.24 Reactor technologies: analytical and computational |
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| 7.00 Inertial confinement |
| 7.01 Advanced diagnostics and measurement innovation |
| 7.02 Analytical and computational techniques |
| 7.03 Machine learning and data science techniques in inertially confined plasmas |
| 7.04 Laser-plasma instabilities |
| 7.05 Z-pinch, X-pinch, exploding wire plasma, and dense plasma focus |
| 7.06 Hohlraum and x-ray cavity physics |
| 7.07 Compression and burn |
| 7.08 Hydrodynamic instability |
| 7.09 ICF concepts and drivers |
| 7.10 Magneto-inertial fusion |
| 7.11 Ignition physics |
| |
| 8.00 High-energy-density science |
| 8.01 Advanced diagnostics and measurement innovation |
| 8.02 Analytical and computational techniques |
| 8.03 Machine learning and data science techniques in high energy density science |
| 8.04 High-energy-density hydrodynamics |
| 8.05 Magnetized high-energy-density plasma |
| 8.06 Warm dense matter |
| 8.07 Nonlinear optics of plasma |
| 8.08 Short-pulse laser-on-plasma interactions |
| 8.09 High-Z, multiply ionized atomic physics |
| 8.10 Equations of state and material properties |
| 8.11 HEDP laboratory astrophysics |
| |
| 9.00 Science Education, Public Engagement and DEIA Efforts |
| 9.01 Science Education and Public Engagement in plasma science/engineering |
| 9.02 Engaging the public with plasma science and engineering |
| 9.03 DEIA efforts in the plasma science/engineering community |
| |
| 10.00 Undergraduate or high school research |
| 10.01 High-school research |
| 10.02 Undergraduate research |
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| 11.00 Mini-Conferences |
| 11.01 Multi-Petawatt Physics at New and Future Laser User Facilities |
| 11.02 Progress in Making IFE-based Concepts a Reality |
| 11.03 Pulsed Magnetic Fusion Energy |
| 11.04 Digital Twins for Fusion Research |
| 11.05 Topological Plasma Physics |
| 11.06 Proton Transport in High Energy Density Plasmas |
| 11.07 Plasma Equilibria, Stability and Nonlinear Dynamics In Honour of Robert Dewar |
| |
| 12.00 Supplemental |