Application of a Synthetic Diagnostic and Comparison to HSX Data
POSTER
Abstract
Transport driven by the nonlinear, turbulent interaction of ion and electron scale fluctuations
plays a critical role in determining the performance of stellarators. Understanding and mitigating
the effects of turbulent transport is crucial for the efficient operation of these devices. With
accurate physics modelling, a path for turbulence optimization on a stellarator design can be
paved. Validation studies, which involve the rigorous comparison of numerical simulations with
experimental data, provide a pathway to enhance theoretical and numerical models of plasma
microturbulence.
In order for a direct comparison, simulated data needs to be modified appropriately through a
synthetic diagnostic, which takes into account the spatial and temporal resolutions of an
experimental diagnostic. A synthetic diagnostic has been created and was applied to an
analytical example [1]. Good agreement was found, giving confidence to the accuracy of the
model. The synthetic diagnostic was also applied to nonlinear flux-tube GENE simulations of
TEM microturbulence at experimentally relevant parameters for the HSX stellarator. Tolerances
for the free parameters of the diagnostic were explored, and acceptable agreement was found
with CECE data. This comparison is a building block for a complete validation study of the
GENE code with HSX. Future work also includes a full validation study for the W7X stellarator.
[1] Bravenec, R. V., & Wootton, A. J. (1995). Effects of limited spatial resolution on Fluctuation
Measurements (invited). Review of Scientific Instruments, 66(1), 802–805.
https://doi.org/10.1063/1.1146226
plays a critical role in determining the performance of stellarators. Understanding and mitigating
the effects of turbulent transport is crucial for the efficient operation of these devices. With
accurate physics modelling, a path for turbulence optimization on a stellarator design can be
paved. Validation studies, which involve the rigorous comparison of numerical simulations with
experimental data, provide a pathway to enhance theoretical and numerical models of plasma
microturbulence.
In order for a direct comparison, simulated data needs to be modified appropriately through a
synthetic diagnostic, which takes into account the spatial and temporal resolutions of an
experimental diagnostic. A synthetic diagnostic has been created and was applied to an
analytical example [1]. Good agreement was found, giving confidence to the accuracy of the
model. The synthetic diagnostic was also applied to nonlinear flux-tube GENE simulations of
TEM microturbulence at experimentally relevant parameters for the HSX stellarator. Tolerances
for the free parameters of the diagnostic were explored, and acceptable agreement was found
with CECE data. This comparison is a building block for a complete validation study of the
GENE code with HSX. Future work also includes a full validation study for the W7X stellarator.
[1] Bravenec, R. V., & Wootton, A. J. (1995). Effects of limited spatial resolution on Fluctuation
Measurements (invited). Review of Scientific Instruments, 66(1), 802–805.
https://doi.org/10.1063/1.1146226
*This work was supported by the U.S. Department of Energy under Grant Nos. DE-SC0021972 and DE-FG02-ER54546
Publication: [1] Bravenec, R. V., & Wootton, A. J. (1995). Effects of limited spatial resolution on Fluctuation
Measurements (invited). Review of Scientific Instruments, 66(1), 802–805.
https://doi.org/10.1063/1.1146226
Presenters
-
Gavin Wayne Held
- University of Wisconsin - Madison