Amplitude and size scaling for interchange motions of plasma filaments

Kube, Ralph; Wiesenberger, Matthias; Garcia, Odd Erik

doi:10.1063/1.4971220

Cited by 14 publications

(18 citation statements)

References 55 publications

(70 reference statements)

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“…5 Applications Programs that execute two-and threedimensional simulations: read in input file(s), simulate, and either write results to disc or directly visualize them on screen. Some examples led to journal publications in the past [63,32,43,62].…”

Section: Overviewmentioning

confidence: 99%

Reproducibility, accuracy and performance of the Feltor code and library on parallel computer architectures

Wiesenberger

Einkemmer

Held

et al. 2019

Computer Physics Communications

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Feltor is a modular and free scientific software package. It allows developing platform independent code that runs on a variety of parallel computer architectures ranging from laptop CPUs to multi-GPU distributed memory systems. Feltor consists of both a numerical library and a collection of application codes built on top of the library. Its main target are two-and three-dimensional drift-and gyro-fluid simulations with discontinuous Galerkin methods as the main numerical discretization technique.We observe that numerical simulations of a recently developed gyro-fluid model produce non-deterministic results in parallel computations. First, we show how we restore accuracy and bitwise reproducibility algorithmically and programmatically. In particular, we adopt an implementation of the exactly rounded dot product based on long accumulators, which avoids accuracy losses especially in parallel applications. However, reproducibility and accuracy alone fail to indicate correct simulation behaviour. In fact, in the physical model slightly different initial conditions lead to vastly different end states. This behaviour translates to its numerical representation. Pointwise convergence, even in principle, becomes impossible for long simulation times. We briefly discuss alternative methods to ensure the correctness of results like the convergence of reduced physical quantities of interest, ensemble simulations, invariants or reduced simulation times.In a second part, we explore important performance tuning considerations. We identify latency and memory bandwidth as the main performance indicators of our routines. Based on these, we propose a parallel performance model that predicts the execution time of algorithms implemented in Feltor and test our model on a selection of parallel hardware architectures. We are able to predict the execution time with a relative error of less than 25% for problem sizes between 10 −1 and 10 3 MB. Finally, we find that the product of latency and bandwidth gives a minimum array size per compute node to achieve a scaling efficiency above 50% (both strong and weak).

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Section: Overviewmentioning

confidence: 99%

Reproducibility, accuracy and performance of the Feltor code and library on parallel computer architectures

Wiesenberger

Einkemmer

Held

et al. 2019

Computer Physics Communications

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“…where we define the entropy S(t) := dA [n ln(n/n 0 ) − (n − n 0 )], the kinetic energy E(t) := m i dA nu 2 E /2 and the potential energies G(t) := m i g dA x(n − n 0 ) and H(t) := T e dA (n−n 0 ) ln(B −1 ). Note that n ln(n/n 0 )− n + n 0 ≈ (n − n 0 ) 2 /2 for |(n − n 0 )/n 0 | 1 and S(t) thus reduces to the local entropy form in Reference [25].…”

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confidence: 99%

Unified transport scaling laws for plasma blobs and depletions

et al. 2017

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We study the dynamics of seeded plasma blobs and depletions in an (effective) gravitational field. For incompressible flows the radial center of mass velocity of blobs and depletions is proportional to the square root of their initial cross-field size and amplitude. If the flows are compressible, this scaling holds only for ratios of amplitude to size larger than a critical value. Otherwise, the maximum blob and depletion velocity depends linearly on the initial amplitude and is independent of size. In both cases the acceleration of blobs and depletions depends on their initial amplitude relative to the background plasma density, is proportional to gravity and independent of their cross-field size. Due to their reduced inertia plasma depletions accelerate more quickly than the corresponding blobs. These scaling laws are derived from the invariants of the governing drift-fluid equations and agree excellently with numerical simulations over five orders of magnitude. We suggest an empirical model that unifies and correctly captures the radial acceleration and maximum velocities of both blobs and depletions

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“…Since detailed physical models increase the analytical complexity significantly, the scientific community relies on numerical simulations of isolated blobs and fully turbulent simulations of the scrape off layer. Numerical simulations in two dimensions [26][27][28][29][30][31][32] and three dimensions [33][34][35][36][37][38][39][40][41] have enhanced the understanding of the underlying mechanisms of blob and filament propagation in the scrape off layer. Most of these numerical simulations investigate idealized isolated blobs modeled as positive symmetrical Gaussian perturbations on a constant plasma background.…”

Section: Introductionmentioning

confidence: 99%

“…This approach has provided an effective way of investigating the influa) Electronic mail: gregor.decristoforo@uit.no (corresponding author); Department of Physics and Technology, UiT The Arctic University of Norway, NO-9037 Tromsø, Norway b) CCFE, Culham Science Centre, Abingdon OX14 3DB, United Kingdom c) Department of Physics and Technology, UiT The Arctic University of Norway, NO-9037 Tromsø, Norway d) York Plasma Institute, Department of Physics, University of York, Heslington, York YO10 5DD, United Kingdom e) University of Birmingham, School of Physics and Astronomy, Edgbaston, Edgbaston Park Road, Birmingham B15 2TT, United Kingdom ence of specific physical effects, such as finite Larmor radius effects 42 , electromagnetic effects 43 or parallel electron dynamics 44 on the blob velocity, coherence and lifetime. Scaling laws describing the radial blob velocity depending on it's amplitudes and size 30,31 have been developed, and different regimes determined by various physical parameters have been discovered 45,46 . Despite this progress, understanding how well these scaling laws describe blobs in fully turbulent scenarios where they interact with each other is non-trivial.…”

Section: Introductionmentioning

confidence: 99%

Blob interactions in 2D scrape-off layer simulations

et al. 2020

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Interaction of coherent structures known as blobs in the scrape-off layer of magnetic confinement fusion devices is investigated. Isolated and interacting seeded blobs as well as full plasma turbulence are studied with a two dimensional fluid code. The features of the blobs (size, amplitude, position) are determined with a blob tracking algorithm, which identifies them as coherent structures above a chosen density threshold and compared to a conventional center of mass approach. The agreement of these two methods is shown to be affected by the parameters of the blob tracking algorithm. The benchmarked approach is then extended to a population of interacting plasma blobs with statistically distributed amplitudes, sizes and initial positions for different levels of intermittency. As expected, for decreasing intermittency, we observe an increasing number of blobs deviating from size-velocity scaling laws of perfectly isolated blobs. This is found to be caused by the interaction of blobs with the electrostatic potential of one another, leading to higher average blob velocities. The degree of variation from the picture of perfectly isolated blobs is quantified as a function of the average waiting time of the seeded blobs.

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Amplitude and size scaling for interchange motions of plasma filaments

Cited by 14 publications

References 55 publications

Reproducibility, accuracy and performance of the Feltor code and library on parallel computer architectures

Reproducibility, accuracy and performance of the Feltor code and library on parallel computer architectures

Unified transport scaling laws for plasma blobs and depletions

Blob interactions in 2D scrape-off layer simulations

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