Phase space effects on fast ion distribution function modeling in tokamaks
Abstract
Integrated simulations of tokamak discharges typically rely on classical physics to model energetic particle (EP) dynamics. However, there are numerous cases in which energetic particles can suffer additional transport that is not classical in nature. Examples include transport by applied 3D magnetic perturbations and, more notably, by plasma instabilities. Focusing on the effects of instabilities, adhoc models can empirically reproduce increased transport, but the choice of transport coefficients is usually somehow arbitrary. New approaches based on physicsbased reduced models are being developed to address those issues in a simplified way, while retaining a more correct treatment of resonant waveparticle interactions. The kick model implemented in the tokamak transport code TRANSP is an example of such reduced models. It includes modifications of the EP distribution by instabilities in real and velocity space, retaining correlations between transport in energy and space typical of resonant EP transport. The relevance of EP phase space modifications by instabilities is first discussed in terms of predicted fast ion distribution. Results are compared with those from a simple, adhoc diffusive model. It is then shown that the phasespace resolved model can also provide additional insight into important issues such as internal consistency of the simulations and modemore »
 Authors:

 Princeton Plasma Physics Lab. (PPPL), Princeton, NJ (United States)
 Publication Date:
 Research Org.:
 Princeton Plasma Physics Lab. (PPPL), Princeton, NJ (United States)
 Sponsoring Org.:
 USDOE Office of Science (SC), Fusion Energy Sciences (FES)
 OSTI Identifier:
 1366480
 DOE Contract Number:
 AC0209CH11466
 Resource Type:
 Data
 Resource Relation:
 Related Information: Physics of Plasmas, Vol. 23, p. 056106 (2016)
 Country of Publication:
 United States
 Language:
 English
 Subject:
 70 PLASMA PHYSICS AND FUSION TECHNOLOGY; Integrated modeling energetic particle distribution energetic particle transport kick model TRANSP NUBEAM
Citation Formats
White, R. B., Podesta, M., Gorelenkova, M., Fredrickson, E. D., and Gorelenkov, N. N. Phase space effects on fast ion distribution function modeling in tokamaks. United States: N. p., 2016.
Web. doi:10.11578/1366480.
White, R. B., Podesta, M., Gorelenkova, M., Fredrickson, E. D., & Gorelenkov, N. N. Phase space effects on fast ion distribution function modeling in tokamaks. United States. doi:10.11578/1366480.
White, R. B., Podesta, M., Gorelenkova, M., Fredrickson, E. D., and Gorelenkov, N. N. Wed .
"Phase space effects on fast ion distribution function modeling in tokamaks". United States. doi:10.11578/1366480. https://www.osti.gov/servlets/purl/1366480.
@article{osti_1366480,
title = {Phase space effects on fast ion distribution function modeling in tokamaks},
author = {White, R. B. and Podesta, M. and Gorelenkova, M. and Fredrickson, E. D. and Gorelenkov, N. N.},
abstractNote = {Integrated simulations of tokamak discharges typically rely on classical physics to model energetic particle (EP) dynamics. However, there are numerous cases in which energetic particles can suffer additional transport that is not classical in nature. Examples include transport by applied 3D magnetic perturbations and, more notably, by plasma instabilities. Focusing on the effects of instabilities, adhoc models can empirically reproduce increased transport, but the choice of transport coefficients is usually somehow arbitrary. New approaches based on physicsbased reduced models are being developed to address those issues in a simplified way, while retaining a more correct treatment of resonant waveparticle interactions. The kick model implemented in the tokamak transport code TRANSP is an example of such reduced models. It includes modifications of the EP distribution by instabilities in real and velocity space, retaining correlations between transport in energy and space typical of resonant EP transport. The relevance of EP phase space modifications by instabilities is first discussed in terms of predicted fast ion distribution. Results are compared with those from a simple, adhoc diffusive model. It is then shown that the phasespace resolved model can also provide additional insight into important issues such as internal consistency of the simulations and mode stability through the analysis of the power exchanged between energetic particles and the instabilities.},
doi = {10.11578/1366480},
journal = {},
number = ,
volume = ,
place = {United States},
year = {2016},
month = {6}
}
Works referencing / citing this record:
Phase space effects on fast ion distribution function modeling in tokamaks
journal, May 2016
 Podestà, M.; Gorelenkova, M.; Fredrickson, E. D.
 Physics of Plasmas, Vol. 23, Issue 5, Article No. 056106
Phase space effects on fast ion distribution function modeling in tokamaks
journal, May 2016
 Podestà, M.; Gorelenkova, M.; Fredrickson, E. D.
 Physics of Plasmas, Vol. 23, Issue 5, Article No. 056106