Progress in theoretical and numerical modeling of RF/MHD coupling using NIMROD

Thomas G. Jenkins; Dalton D. Schnack; C.C. Hegna; James D. Callen; Carl R. Sovinec; Eric D. Held; Jeong-Young Ji; S. Kruger

Progress in theoretical and numerical modeling of RF/MHD coupling using NIMROD

POSTER

Abstract

Preliminary work relevant to the development of a general framework for the self-consistent inclusion of RF effects in fluid codes is presented; specifically, the stabilization of neoclassical and conventional tearing modes by electron cyclotron current drive is considered. For this particular problem, the effects of the RF drive can be formally captured by a quasilinear diffusion operator which enters the fluid equations on the same footing as the collision operator. Furthermore, a Chapman-Enskog-like method can be used to determine the consequent effects of the RF drive on the fluid closures for the parallel heat flow and stress. We summarize our recent research along these lines and discuss issues relevant to its implementation in the NIMROD code.

^*Work performed as part of the SWIM project, supported by U.S. DoE.

Authors

Thomas G. Jenkins
- University of Wisconsin-Madison
Dalton D. Schnack
- Univ. of Wisconsin-Madison
- University of Wisconsin-Madison
C.C. Hegna
- University of Wisconsin
- University of Wisconsin-Madison
James D. Callen
- University of Wisconsin-Madison
- University of Wisconsin
Carl R. Sovinec
- University of Wisconsin and the Center for Magnetic Self-Organization in Laboratory and Astrophysical Plasmas
- Univ. of Wisconsin - Madison
- University of Wisconsin-Madison
Eric D. Held
- Utah State University
Jeong-Young Ji
- Utah State University
S. Kruger
- Tech-X Corporation
- Tech-X Corp.