Presentation is loading. Please wait.

Presentation is loading. Please wait.

Kinetic Modeling of the Sheath Scale in the Lunar Plasma Environment Tech-X Corporation 5621 Arapahoe Ave., Boulder, CO 80303 Peter.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Kinetic Modeling of the Sheath Scale in the Lunar Plasma Environment Tech-X Corporation 5621 Arapahoe Ave., Boulder, CO 80303 Peter."— Presentation transcript:

1 Kinetic Modeling of the Sheath Scale in the Lunar Plasma Environment Tech-X Corporation 5621 Arapahoe Ave., Boulder, CO 80303 http://www.txcorp.com Peter Messmer*, Keegan Amyx, Peter Stoltz, Andrew Poppe, Mihay Horanyi, Scott Robertson, Zoltan Sternovsky messmer@txcorp.com CCLDAS All Hands Meeting, Boulder, CO, July 10, 2009

2 VORPAL - A Plasma Modeling Framework Original target applications: Laser Wakefield Acceleration PIC, Fluid, Hybird Electrostatic, EM Multi-Dimensional (N=1,2,3) Fully parallel Scaling for > 32,000 PEs Flexible domain decomposition Broad range of physics features : -Complex geometries -Ionization, recombination, CEX physics -Field ionization http://www.txcorp.com/products/VORPAL

3 Code/setup Validation with 1D Photoelectron Sheath R. Garad & J Tunaley, JGR 76(10), 2498, 1971 A. Poppe & M. Horanyi, WPDP, 2009 2D ES simulation, Y periodic, 200 x 10 cells   dx = 10 50 particles per cell nominal Simulation Garad&Tunaley Monoenergetic Maxwellian

4 2D Monoenergetic Sheath 2D ES simulation, left wall = 0V 200 x 100 cells Electrons, Protons Monoenergetic,V 0 = 200 eV (!) electrons protons  

5 Scenario with Surface Charging Surface-Charging No surface charging (just for comparison)

6 2D Thermal Sheath with Surface Charging 2D ES simulation, left wall = 0V 200 x 100 cells Electrons Heavy Protons, Heavy electrons (m/m 0 = 5000) Vsig = 3eV, V therm = 3 eV Electron impact creates “heavy electrons” Electrons get absorbed

7 Electric field mainly due to positive charge of emitting region Charging Non Charging

8 “Heavy Electrons” follow the electric field lines 2D ES simulation, left wall = 0V 200 x 100 cells Electrons Heavy Protons, Heavy electrons (m/m 0 = 5000) Vsig = 3eV, V therm = 3 eV

9 Initial 3D simulations 3D ES simulation, bottom wall = 0V 10 x 100 x 100 cells Electrons Protons, Heavy electrons (m/m 0 = 5000) Vsig = 3eV, V therm = 3 eV Charging of surface No charging of surface

10 Summary / Conclusions / Future work  Presented VORPAL simulations of plasma sheath  Validated with kinetic theory for 1D sheath  Presented 2D simulation with/without surface charging  “heavy electrons” move in electrostatic field, follow (curved) field lines Future work:  Convergence studies, more realistic parameters  Inclusion of solar wind  Time dependent problems, angular dependency of photo-currents  Complex geometries (crater, habitat, instrument)  3D Work supported by CCLDAS and Tech-X Corp.

Download ppt "Kinetic Modeling of the Sheath Scale in the Lunar Plasma Environment Tech-X Corporation 5621 Arapahoe Ave., Boulder, CO 80303 Peter."

Similar presentations

Anomalous Ion Heating Status and Research Plan

Anomalous Ion Heating Status and Research Plan
Plasma Medicine in Vorpal Tech-X Workshop / ICOPS 2012, Edinburgh, UK 8-12 July, 2012 Alexandre Likhanskii Tech-X Corporation.

Plasma Medicine in Vorpal Tech-X Workshop / ICOPS 2012, Edinburgh, UK 8-12 July, 2012 Alexandre Likhanskii Tech-X Corporation.
SOLAR WIND TURBULENCE; WAVE DISSIPATION AT ELECTRON SCALE WAVELENGTHS S. Peter Gary Space Science Institute Boulder, CO Meeting on Solar Wind Turbulence.

SOLAR WIND TURBULENCE; WAVE DISSIPATION AT ELECTRON SCALE WAVELENGTHS S. Peter Gary Space Science Institute Boulder, CO Meeting on Solar Wind Turbulence.
Stefan Roesler SC-RP/CERN on behalf of the CERN-SLAC RP Collaboration

Stefan Roesler SC-RP/CERN on behalf of the CERN-SLAC RP Collaboration
Erdem Oz* USC E-164X,E167 Collaboration Plasma Dark Current in Self-Ionized Plasma Wake Field Accelerators

Erdem Oz* USC E-164X,E167 Collaboration Plasma Dark Current in Self-Ionized Plasma Wake Field Accelerators
Ion Pickup One of the fundamental processes in space plasma physics.

Ion Pickup One of the fundamental processes in space plasma physics.
Lunar Results Hybrid code. Initial condition Amplitude of dipole for the moon= 0 Lunar Radius=16.9 (unit of length) Maximum time = 200(inverse of gyro.

Lunar Results Hybrid code. Initial condition Amplitude of dipole for the moon= 0 Lunar Radius=16.9 (unit of length) Maximum time = 200(inverse of gyro.
Alfvén-cyclotron wave mode structure: linear and nonlinear behavior J. A. Araneda 1, H. Astudillo 1, and E. Marsch 2 1 Departamento de Física, Universidad.

Alfvén-cyclotron wave mode structure: linear and nonlinear behavior J. A. Araneda 1, H. Astudillo 1, and E. Marsch 2 1 Departamento de Física, Universidad.
Modeling Generation and Nonlinear Evolution of Plasma Turbulence for Radiation Belt Remediation Center for Space Science & Engineering Research Virginia.

Modeling Generation and Nonlinear Evolution of Plasma Turbulence for Radiation Belt Remediation Center for Space Science & Engineering Research Virginia.
Breakdown – Phase I K. Paul, S. Veitzer, P. Stoltz, D. Smithe (Tech-X) J. Norem (Argonne National Lab) Tech-X Corporation August.

Breakdown – Phase I K. Paul, S. Veitzer, P. Stoltz, D. Smithe (Tech-X) J. Norem (Argonne National Lab) Tech-X Corporation August.
Solar Flare Particle Heating via low-beta Reconnection Dietmar Krauss-Varban & Brian T. Welsch Space Sciences Laboratory UC Berkeley Reconnection Workshop.

Solar Flare Particle Heating via low-beta Reconnection Dietmar Krauss-Varban & Brian T. Welsch Space Sciences Laboratory UC Berkeley Reconnection Workshop.
Hybrid Simulation of Ion-Cyclotron Turbulence Induced by Artificial Plasma Cloud in the Magnetosphere W. Scales, J. Wang, C. Chang Center for Space Science.

Hybrid Simulation of Ion-Cyclotron Turbulence Induced by Artificial Plasma Cloud in the Magnetosphere W. Scales, J. Wang, C. Chang Center for Space Science.
Computational Modeling Capabilities for Neutral Gas Injection Wayne Scales and Joseph Wang Virginia Tech Center for Space Science and Engineering.

Computational Modeling Capabilities for Neutral Gas Injection Wayne Scales and Joseph Wang Virginia Tech Center for Space Science and Engineering.
An Introduction to Breakdown Simulations With PIC Codes C. Nieter, S.A. Veitzer, S. Mahalingam, P. Stoltz Tech-X Corporation MTA RF Workshop 2008 Particle-in-Cell.

An Introduction to Breakdown Simulations With PIC Codes C. Nieter, S.A. Veitzer, S. Mahalingam, P. Stoltz Tech-X Corporation MTA RF Workshop 2008 Particle-in-Cell.
NLSI meeting, NASA Ames, July 2009 The Lunar Dust EXperiment (LDEX) for the Lunar Atmosphere and Dust Environment Explorer (LADEE) Mission Z. Sternovsky,

NLSI meeting, NASA Ames, July 2009 The Lunar Dust EXperiment (LDEX) for the Lunar Atmosphere and Dust Environment Explorer (LADEE) Mission Z. Sternovsky,
March 13, 2009 - CCLDAS Particle-in-Cell Simulations of the Lunar Dusty Plasma Environment A. Poppe & M. Horányi Laboratory for Atmospheric and Space Physics.

March 13, CCLDAS Particle-in-Cell Simulations of the Lunar Dusty Plasma Environment A. Poppe & M. Horányi Laboratory for Atmospheric and Space Physics.
Boundaries in the auroral region --- Small scale density cavities and associated processes --- Vincent Génot (CESR/CNRS) C. Chaston (SSL) P. Louarn (CESR/CNRS)

Boundaries in the auroral region --- Small scale density cavities and associated processes --- Vincent Génot (CESR/CNRS) C. Chaston (SSL) P. Louarn (CESR/CNRS)
Ultra-High-Intensity Laser-Plasma Interactions: Comparing Experimental Results with Three- Dimensional,Fully-Relativistic, Numerical Simultations Donald.

Ultra-High-Intensity Laser-Plasma Interactions: Comparing Experimental Results with Three- Dimensional,Fully-Relativistic, Numerical Simultations Donald.
Operated by Brookhaven Science Associates for the U.S. Department of Energy Optimized Parameters for a Mercury Jet Target X. Ding, D. Cline, UCLA, Los.

Operated by Brookhaven Science Associates for the U.S. Department of Energy Optimized Parameters for a Mercury Jet Target X. Ding, D. Cline, UCLA, Los.
VORPAL for Simulating RF Breakdown Kevin Paul VORPAL is a massively-parallel, fully electromagnetic particle- in-cell (PIC) code, originally.

VORPAL for Simulating RF Breakdown Kevin Paul VORPAL is a massively-parallel, fully electromagnetic particle- in-cell (PIC) code, originally.

Similar presentations

Ads by Google