The GBS code for the self-consistent simulation of plasma turbulence and kinetic neutral dynamics in the tokamak boundary

Abstract: A new version of GBS (Ricci et al.

“…In this letter we present results of the first global, two-fluid, flux-driven simulation of a stellarator with an island divertor. The simulation is performed with the GBS code, which has been used in the past decade to simulate the tokamak boundary [22][23][24][25][26][27][28], and it is here extended to non-axisymmetric magnetic fields. GBS solves the drift-reduced Braginskii equations [29], valid in the high collisionality regime, which is often justified in the plasma boundary of magnetic fusion devices as well as in the core of low-temperature devices (e.g., TJ-K [30]).…”

“…All quantities are evolved in time without separation between equilibrium and fluctuating parts. We consider here the electrostatic limit, we apply the Boussinesq approximation [22], and we neglect gyroviscous terms as well as the coupling to the neutral dynamics, although these are implemented in the most recent version of the GBS code for tokamak simulations [23]. Within these approximations, the drift-reduced model evolved by GBS is:…”

Global fluid simulation of plasma turbulence in a stellarator with an island divertor

“…In this letter we present results of the first global, two-fluid, flux-driven simulation of a stellarator with an island divertor. The simulation is performed with the GBS code, which has been used in the past decade to simulate the tokamak boundary [22][23][24][25][26][27][28], and it is here extended to non-axisymmetric magnetic fields. GBS solves the drift-reduced Braginskii equations [29], valid in the high collisionality regime, which is often justified in the plasma boundary of magnetic fusion devices as well as in the core of low-temperature devices (e.g., TJ-K [30]).…”

“…All quantities are evolved in time without separation between equilibrium and fluctuating parts. We consider here the electrostatic limit, we apply the Boussinesq approximation [22], and we neglect gyroviscous terms as well as the coupling to the neutral dynamics, although these are implemented in the most recent version of the GBS code for tokamak simulations [23]. Within these approximations, the drift-reduced model evolved by GBS is:…”

Global fluid simulation of plasma turbulence in a stellarator with an island divertor

“…In this Letter we present results of the first global, two-fluid, flux-driven simulation of a stellarator with an island divertor. The simulation is performed with the GBS code, which has been used in the past decade to simulate the tokamak boundary [20,21,22,23,24,25,26], and it is here extended to non-axisymmetric magnetic fields. GBS solves the drift-reduced Braginskii equations [27], valid in the high collisionality regime, which is often justified in the plasma boundary of magnetic fusion devices as well as in the core of low-temperature devices (e.g., TJ-K [28]).…”

“…All quantities are evolved in time without separation between equilibrium and fluctuating parts. We consider here the electrostatic limit, we apply the Boussinesq approximation [20], and we neglect gyroviscous terms as well as the coupling to the neutral dynamics, although these are implemented in the most recent version of the GBS code for tokamak simulations [21]. Within these approximations, the drift-reduced model evolved by GBS is:…”

Global fluid simulation of plasma turbulence in a stellarator with an island divertor