Theoretical Plasma Physics

Vahala, George M.

doi:10.2172/1247483

Title: Theoretical Plasma Physics

Full Record
Other Related Research

Abstract

Lattice Boltzmann algorithms are a mesoscopic method to solve problems in nonlinear physics which are highly parallelized – unlike the direction solution of the original problem. These methods are applied to both fluid and magnetohydrodynamic turbulence. By introducing entropic constraints one can enforce the positive definiteness of the distribution functions and so be able to simulate fluids at high Reynolds numbers without numerical instabilities. By introducing a vector distribution function for the magnetic field one can enforce the divergence free condition on the magnetic field automatically, without the need of divergence cleaning as needed in most direct numerical solutions of the resistive magnetohydrodynamic equations. The principal reason for the high parallelization of lattice Boltzmann codes is that they consist of a kinetic collisional relaxation step (which is purely local) followed by a simple shift of the relaxed data to neighboring lattice sites. In large eddy simulations, the closure schemes are highly nonlocal – the most famous of these schemes is that due to Smagorinsky. Under a lattice Boltzmann representation the Smagorinsky closure is purely local – being simply a particular moment on the perturbed distribution fucntions. After nonlocal fluid moment models were discovered to represent Landau damping, it was foundmore »« less

Authors:

Vahala, George M. ^[1]

College of William and Mary, Williamsburg, VA (United States)

Publication Date:: Tue Dec 31 00:00:00 EST 2013

Research Org.:: College of William and Mary, Williamsburg, VA (United States)

Sponsoring Org.:: USDOE Office of Science (SC)

OSTI Identifier:: 1247483

Report Number(s):: DOE-CWM-54344

DOE Contract Number:: FG02-96ER54344

Resource Type:: Technical Report

Country of Publication:: United States

Language:: English

Subject:: 70 PLASMA PHYSICS AND FUSION TECHNOLOGY; lattice Boltzmann; Resistive Magnetohydrodynamics; electron Bernstein waves; quasi-optical grills; Multi-junction Grills; lower Hybrid waves; NSTX; MAST

Citation Formats


                    Vahala, George M. Theoretical Plasma Physics.  United States: N. p., 2013. 
        Web.  doi:10.2172/1247483.

Copy to clipboard


                    Vahala, George M. Theoretical Plasma Physics.  United States.  https://doi.org/10.2172/1247483

Copy to clipboard


                    Vahala, George M. 2013.  
        "Theoretical Plasma Physics".  United States.  https://doi.org/10.2172/1247483.  https://www.osti.gov/servlets/purl/1247483.

Copy to clipboard


                    
@article{osti_1247483,

  title        = {Theoretical Plasma Physics},

  author       = {Vahala, George M.},

  abstractNote = {Lattice Boltzmann algorithms are a mesoscopic method to solve problems in nonlinear physics which are highly parallelized – unlike the direction solution of the original problem. These methods are applied to both fluid and magnetohydrodynamic turbulence. By introducing entropic constraints one can enforce the positive definiteness of the distribution functions and so be able to simulate fluids at high Reynolds numbers without numerical instabilities. By introducing a vector distribution function for the magnetic field one can enforce the divergence free condition on the magnetic field automatically, without the need of divergence cleaning as needed in most direct numerical solutions of the resistive magnetohydrodynamic equations. The principal reason for the high parallelization of lattice Boltzmann codes is that they consist of a kinetic collisional relaxation step (which is purely local) followed by a simple shift of the relaxed data to neighboring lattice sites. In large eddy simulations, the closure schemes are highly nonlocal – the most famous of these schemes is that due to Smagorinsky. Under a lattice Boltzmann representation the Smagorinsky closure is purely local – being simply a particular moment on the perturbed distribution fucntions. After nonlocal fluid moment models were discovered to represent Landau damping, it was found possible to model these fluid models using an appropriate lattice Boltzmann algorithm. The close to ideal parallelization of the lattice Boltzmann codes permitted us to be Gordon Bell finalists on using the Earth Simulation in Japan. We have also been involved in the radio frequency propagation of waves into a tokamak and into a spherical overdense tokamak plasma. Initially we investigated the use of a quasi-optical grill for the launching of lower hybrid waves into a tokamak. It was found that the conducting walls do not prevent the rods from being properly irradiated, the overloading of the quasi-optical grill is not severe with the electric field only being about three times higher than in the ideal case. Moreover, the quasi-optical grill was significantly fewer structural elements that the multijunction grill. Nevertheless there has not been much interest from experimental fusion groups to implementing these structures. Hence we have returned to optimizing the multijunction grill so that the large number of coupling matrix elements can be efficiently evaluated using symmetry arguments. In overdense plasmas, the standard electromagnetic waves cannot propagate into the plasma center, but are reflected at the plasma edge. By optimizing mode conversion processes (in particular, the O-X-B wave propagation of Ordinary Mode converting to an Extraordinary mode which then converts into an electrostatic Bernstein wave) one can excite within the plasma an electrostatic Bernstein wave that does not suffer density cutoffs and is absorbed on the electron cyclotron harmonics. Finally we have started looking at other mesoscopic lattice algorithms that involve unitary collision and streaming steps. Because these algorithms are unitary they can be run on quantum computers when they become available – unlike their computational cousin of lattice Boltzmann which is a purely classical code. These quantum lattice gas algorithms have been tested successfully on exact analytic soliton collision solution. These calculations are hoped to be able to study Bose Einstein condensed atomic gases and their ground states in an optical lattice.},

  doi          = {10.2172/1247483},

  url          = {https://www.osti.gov/biblio/1247483},
  journal      = {},
number       = ,

  volume       = ,

  place        = {United States},

  year         = {Tue Dec 31 00:00:00 EST 2013},

  month        = {Tue Dec 31 00:00:00 EST 2013}

}

Copy to clipboard

Technical Report:

View Technical Report (5.66 MB)

https://doi.org/10.2172/1247483

Save / Share:

Export Metadata

Save to My Library

Similar records in OSTI.GOV collections:

Chapter 11: The Heating and Current Drive Systems of the FTU

Journal Article Aquilini, M; Baldi, L; Bibet, P; ... - Fusion Science and Technology

High-frequency wave systems with high-power density launching capability have been the preferred choice to heat the Frascati Tokamak Upgrade (FTU) because of physics arguments (electron heating at very high density) and space constraints from the compactness of the machine design (8-cm-wide port). They do include an 8-GHz lower hybrid current drive (LHCD) system, a 140-GHz electron cyclotron resonance heating (ECRH) system, and a 433-MHz ion Bernstein waves system (IBW). The technical aspects of these systems will be reviewed in this article. The main features of the design include the following: (a) a very compact conventional LHCD grill with a compactmore »« less
Final Technical Report (Phase I) 3D full wave iterative RF beams simulation tool

Technical Report Svidzinski, Vladimir

Radio-frequency beams in the electron cyclotron resonance frequency range are used to heat plasma and to drive current in most fusion devices such as Tokamaks, Stellarators and Reversed Field Pinches. RF power absorption at fundamental electron cyclotron resonance or its harmonics and damping of mode converted electron Bernstein waves are being studied as the main plasma heating and control methods in future fusion reactors. Radio-frequency technologies in plasma and other dielectric media also have numerous applications beyond fusion. However, an accurate practical modeling of radio-frequency beams in plasma devices is very limited by the large spatial resolution, computer memory andmore »« less
Electron Bernstein Wave Research on NSTX and PEGASUS

Journal Article Diem, S; LeBlanc, B; Taylor, G; ... - AIP Conference Proceedings

Spherical tokamaks (STs) routinely operate in the overdense regime ({omega}{sub pe}>>{omega}{sub ce}), prohibiting the use of standard ECCD and ECRH. However, the electrostatic electron Bernstein wave (EBW) can propagate in the overdense regime and is strongly absorbed and emitted at the electron cyclotron resonances. As such, EBWs offer the potential for local electron temperature measurements and local electron heating and current drive. A critical challenge for these applications is to establish efficient coupling between the EBWs and electromagnetic waves outside the cutoff layer. Two STs in the U.S., the National Spherical Tokamak Experiment (NSTX, at Princeton Plasma Physics Laboratory) andmore »« less
https://doi.org/10.1063/1.2800504
Mode-conversion of the extraordinary wave at the upper hybrid resonance in the presence of small-amplitude density fluctuations

Dataset Lopez, N.; Ram, A.

In spherical tokamaks, the electron plasma frequency is greater than the electron cyclotron frequency. Electromagnetic waves in the electron cyclotron range of frequencies are unsuitable for directly heating such plasmas due to their reduced accessibility. However, mode-conversion of the extraordinary wave to the electron Bernstein wave (X-B mode-conversion) at the upper hybrid resonance makes it possible to efficiently couple externally-launched electromagnetic wave energy into an overdense plasma core. Traditional mode-conversion models describe an X-mode wave propagating in a potential containing two cutoffs that bracket a single wave resonance. Often, however, the mode-conversion region is in the edge, where turbulent fluctuationsmore »« less
https://doi.org/10.7910/DVN/BMYBAV

View Dataset
Mode-conversion of the extraordinary wave at the upper hybrid resonance in the presence of small-amplitude density fluctuations

Journal Article Lopez, N.; Ram, A. - Plasma Physics and Controlled Fusion

We report in spherical tokamaks, the electron plasma frequency is greater than the electron cyclotron (EC) frequency. Electromagnetic waves in the EC range of frequencies are unsuitable for directly heating such plasmas due to their reduced accessibility. However, mode-conversion of the extraordinary wave to the electron Bernstein wave (X–B mode-conversion) at the upper hybrid resonance makes it possible to efficiently couple externally-launched electromagnetic wave energy into an overdense plasma core. Traditional mode-conversion models describe an X-mode wave propagating in a potential containing two cutoffs that bracket a single wave resonance. Often, however, the mode-conversion region is in the edge, wheremore »« less
Cited by 6
https://doi.org/10.1088/1361-6587/aae95e

Full Text Available

Similar Records