Abstract
We present a new method for formulating closures that learn from kinetic simulation data. We apply this method to phase mixing in a simple gyrokinetic turbulent system – temperature-gradient-driven turbulence in an unsheared slab. The closure, called the learned multi-mode (LMM) closure, is constructed by, first, extracting an optimal basis from a nonlinear kinetic simulation using singular value decomposition. Subsequent nonlinear fluid simulations are projected onto this basis and the results are used to formulate the closure. We compare the closure with other closures schemes over a broad range of the relevant two-dimensional parameter space (collisionality and gradient drive). We find that the turbulent kinetic system produces phase-mixing rates much lower than the linear expectations, which the LMM closure is capable of capturing. We also compare radial heat fluxes. A Hammett–Perkins closure, generalized to include collisional effects, is quite successful throughout the parameter space, producing${\sim }14\,\%$root-mean-square (r.m.s.) error. The LMM closure is also very effective: when trained at three (two) points (in a 35 point parameter grid), the LMM closure produces$8\,\%$($12\,\%$) r.m.s. errors. The LMM procedure can be readily generalized to other closure problems.
Highlights
The gyrokinetic model (Frieman & Chen 1982; Krommes 2012; Abel et al 2013), in which the fast gyration of particles around the magnetic field is averaged out, has proven to be a useful description of strongly magnetized plasmas
We have introduced the learned multi-mode (LMM) closure – a new method for formulating closures based on kinetic simulation data
It is applied to the problem of phase mixing in a relatively simple turbulent system – gradient-driven turbulence in an unsheared slab
Summary
The gyrokinetic model (Frieman & Chen 1982; Krommes 2012; Abel et al 2013), in which the fast gyration of particles around the magnetic field is averaged out, has proven to be a useful description of strongly magnetized plasmas. Further reductions in complexity remain highly desirable One such approach to further reducing the gyrokinetic system, the gyrofluid framework, was introduced in Hammett & Perkins (1990) and Dorland & Hammett (1993). This was a major breakthrough, providing a much more rigorous treatment of collisionless plasmas than conventional fluid theory It effectively models phase mixing/Landau damping rates resulting in linear growth rates and frequencies in quite good agreement with the true (kinetic) values. The closure schemes are examined in nonlinear simulations over a broad range of parameter space through the lens of two metrics: (i) the phase-mixing rate, and (ii) the radial heat flux. Despite limitations in reproducing turbulent phase-mixing rates, the HP closure is much more accurate in reproducing the kinetic values of the radial heat flux. Advantages, limitations, and possible future avenues of research are described in the concluding § 6
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