Development of a Global Toroidal Gyrokinetic Vlasov Code with New Real Space Field Solver

This work introduces a new full-f toroidal gyrokinetic (GK) Vlasov simulation code that uses a real space field solver. This solver enables us to compute the gyro-averaging operators in real space to allow proper treatment of finite Larmor radius (FLR) effects without requiring any particular hypoth...

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Veröffentlicht in:	Plasma and Fusion Research 2015/04/16, Vol.10, pp.3403042-3403042
Hauptverfasser:	OBREJAN, Kevin, IMADERA, Kenji, LI, Ji-Quan, KISHIMOTO, Yasuaki
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation field solver finite Larmor radius effect Flow stability Gyrokinetics Ion temperature Larmor radius Magnetic field configurations Temperature gradients Vlasov simulation Zonal flow (meteorology)
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creator	OBREJAN, Kevin IMADERA, Kenji LI, Ji-Quan KISHIMOTO, Yasuaki
description	This work introduces a new full-f toroidal gyrokinetic (GK) Vlasov simulation code that uses a real space field solver. This solver enables us to compute the gyro-averaging operators in real space to allow proper treatment of finite Larmor radius (FLR) effects without requiring any particular hypothesis and in any magnetic field configuration (X-point, D-shaped etc). The code was well verified through benchmark tests such as toroidal Ion Temperature Gradient (ITG) instability and collisionless damping of zonal flow.
doi_str_mv	10.1585/pfr.10.3403042
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subjects	Computer simulation field solver finite Larmor radius effect Flow stability Gyrokinetics Ion temperature Larmor radius Magnetic field configurations Temperature gradients Vlasov simulation Zonal flow (meteorology)
title	Development of a Global Toroidal Gyrokinetic Vlasov Code with New Real Space Field Solver
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