Abstract Sorting
Sorting CategoriesSubmissions should include a DPP sorting category from the list below. Sorting categories are used to assign contributed abstracts to a session. Each contributed abstract must indicate both a "type" category and a "subject classification" category in order to be assigned to an appropriate session. Group abstract placement must be specified in numerical order in the "Special Instructions" field. Type CategoriesChoose one Type category.
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Subject Classification Categories
Choose one Subject Classification Category| 1.0.0 Basic plasma physics | ||
| 1.1.0 Elementary processes in plasmas 1.2.0 Plasma properties | ||
| 1.2.1 Basic studies of specific kinds of plasmas 1.2.2 Single-component, electron-positive-ion plasmas 1.2.3 Multi-component and negative-ion plasmas 1.2.4 Electron-positron plasmas 1.2.5 Strongly coupled plasmas 1.2.6 Non-neutral plasmas 1.2.7 Dusty or complex plasmas 1.2.8 Low temperature or partially ionized plasmas 1.2.9 Relativistic plasmas | ||
| 1.3.0 Plasma dynamics and flow | ||
| 1.3.1 Plasma magnetohydrodynamics 1.3.2 Two-fluid and multi-fluid plasmas 1.3.3 Chaos and self-organization 1.3.4 Gyrokinetics in plasmas | ||
| 1.4.0 Waves, oscillations and instabilities | ||
| 1.4.1 Plasma linear waves 1.4.2 Nonlinear phenomena 1.4.3 Plasma solitons 1.4.4 Magnetic reconnection 1.4.5 Plasma vorticity 1.4.6 Plasma micro-instabilities 1.4.7 Turbulence and transport | ||
| 1.5.0 Shock waves and discontinuities 1.6.0 Plasma interactions: sheaths, boundary layers 1.7.0 Plasma production, sources and heating 1.8.0 Other topics in basic plasma physics 1.9.0 Simulation and modeling of basic plasma phenomena | ||
| 2.0.0 Beams and coherent radiation | ||
| 2.1.0 Beam transport, focusing, conditioning, and instabilities | ||
| 2.1.1 Ion beams and accelerators 2.1.2 Electron beams and accelerators | ||
| 2.2.0 Coherent radiation sources | ||
| 2.2.1 High power microwaves and mm waves 2.2.2 Free electron lasers 2.2.3 Ultra high intensity lasers and harmonic generation (non-IC/IFE) 2.2.4 High harmonic generation 2.2.5 X-ray lasers | ||
| 2.3.0 Laser and plasma based electron accelerators | ||
| 2.3.1 Laser driven accelerators 2.3.2 Laser propagation: non- IC/IFE and Fast Ignition 2.3.3 Beam-driven accelerators and lenses | ||
| 2.4.0 Other topics in beams and coherent radiation 2.5.0 Simulation and modeling of beams and coherent radiation | ||
| 3.0.0 Education and outreach | ||
| 3.1.0 Training, K-12 research | ||
| 4.0.0 Inertial confinement [IC] and high energy density plasmas [HEDP] | ||
| 4.1.0 Plasma heating | ||
| 4.1.1 Laser-plasma coupling at long scale lengths 4.1.2 High-intensity, short-pulse laser plasma interactions 4.1.3 Interactions of intense ion beams and accelerated plasmas with matter | ||
| 4.2.0 Incoherent radiation sources | ||
| 4.2.1 Z-pinches, X-pinches, and dense plasma focus 4.2.2 Intense incoherent radiation generators | ||
| 4.3.0 Hohlraum physics 4.4.0 Compression and burn 4.5.0 Hydrodynamic instability 4.6.0 Fast ignition 4.7.0 Equations of state for HEDP 4.8.0 Target fabrication developments 4.9.0 Inertial fusion energy [IFE] | ||
| 4.9.1 IFE reactor studies 4.9.2 High-average power IFE drivers and systems | ||
| 4.10.0 Diagnostics 4.11.0 Other topics in IC and HEDP 4.12.0 Simulation and modeling of IC and HEDP | ||
| 5.0.0 Magnetic confinement [MC] | ||
| 5.1.0 Turbulence and transport 5.2.0 Magnetohydrodynamics and stability 5.3.0 Heating and current drive 5.4.0 Divertors, edge physics, and fueling 5.5.0 ITER and Magnetic Fusion Development 5.6.0 Plasma confinement configurations | ||
| 5.6.1 General tokamak 5.6.2 DIII-D tokamak 5.6.3 C-Mod tokamak 5.6.4 General spherical torus 5.6.5 NSTX spherical torus 5.6.6 Stellarator 5.6.7 Reversed field pinch 5.6.8 Field reversed configuration and spheromaks | ||
| 5.7.0 Diagnostics 5.8.0 Other topics in MC physics 5.9.0 Simulation and modeling of MC | ||
| 6.0.0 Plasma technology | ||
| 6.1.0 Magnetic confinement technology | ||
| 6.1.1 Plasma heating/current drive and fueling 6.1.2 Plasma facing components 6.1.3 Plasma control systems | ||
| 6.2.0 Inertial confinement technology | ||
| 6.2.1 Drivers and pulsed power technology 6.2.2 Targets 6.2.3 Cryogenic systems | ||
| 6.3.0 Other fusion and neutron generation studies 6.4.0 Diagnostic development and technology 6.5.0 Fusion power plant and system studies 6.6.0 Simulation and modeling of plasma technology | ||
| 7.0.0 Low Temperature Plasmas | ||
| 7.1.0 Plasma sources 7.2.0 Plasma chemistry and plasma surface interactions 7.3.0 Electric propulsion 7.4.0 Lighting, plasma displays, and lasers 7.5.0 Microplasmas 7.6.0 Atmospheric pressure plasmas 7.7.0 Basic processes and techniques | ||
| 7.7.1 Cross-sections, transport coefficients 7.7.2 Diagnostics | ||
| 7.8.0 Other processes and technologies 7.9.0 Simulation and modeling of low temperature plasmas | ||
| 8.0.0 Space and Astrophysical Plasmas | ||
| 8.1.0 Ionospheric plasmas 8.2.0 Magnetospheric plasmas 8.3.0 Interplanetary space plasmas 8.4.0 Solar and heliospheric plasmas 8.5.0 Late stellar evolution plasmas 8.6.0 Plasmas of the interstellar medium and star formation 8.7.0 Laboratory astrophysics 8.8.0 Other topics in space and astrophysical plasmas 8.9.0 Simulation and modeling of space and astrophysical plasmas | ||
| 9.0.0 Other plasma topics 10.0.0 Undergraduate/High School Research | ||
| 11.0.0 Mini-Conference: The Plasma Physics of the Solar Wind: From Parker (1958) to Present | ||
| 12.0.0 Supplemental 13.0.0 Postdeadline | ||
