TY - JOUR
T1 - Non-linear simulations of MHD instabilities in tokamaks including eddy current effects and perspectives for the extension to halo currents
AU - Hoelzl, M.
AU - Huijsmans, G.T.A.
AU - Merkel, P.
AU - Atanasiu, C.
AU - Lackner, K.
AU - Nardon, E.
AU - Aleynikova, K.
AU - Liu, F.
AU - Strumberger, E.
AU - McAdams, R.
AU - Chapman, I.
AU - Fil, A.
PY - 2014/11/1
Y1 - 2014/11/1
N2 - The dynamics of large scale plasma instabilities can be strongly
influenced by the mutual interaction with currents flowing in conducting
vessel structures. Especially eddy currents caused by time-varying
magnetic perturbations and halo currents flowing directly from the
plasma into the walls are important.
The relevance of a resistive wall model is directly evident for
Resistive Wall Modes (RWMs) or Vertical Displacement Events (VDEs).
However, also the linear and non-linear properties of most other
large-scale instabilities may be influenced significantly by the
interaction with currents in conducting structures near the plasma. The
understanding of halo currents arising during disruptions and VDEs,
which are a serious concern for ITER as they may lead to strong
asymmetric forces on vessel structures, could also benefit strongly from
these non-linear modeling capabilities.
Modeling the plasma dynamics and its interaction with wall currents
requires solving the magneto-hydrodynamic (MHD) equations in realistic
toroidal X-point geometry consistently coupled with a model for the
vacuum region and the resistive conducting structures. With this in
mind, the non-linear finite element MHD code JOREK [1, 2] has been
coupled [3] with the resistive wall code STARWALL [4], which allows us
to include the effects of eddy currents in 3D conducting structures in
non-linear MHD simulations.
This article summarizes the capabilities of the coupled JOREK-STARWALL
system and presents benchmark results as well as first applications to
non-linear simulations of RWMs, VDEs, disruptions triggered by massive
gas injection, and Quiescent H-Mode. As an outlook, the perspectives for
extending the model to halo currents are described.
AB - The dynamics of large scale plasma instabilities can be strongly
influenced by the mutual interaction with currents flowing in conducting
vessel structures. Especially eddy currents caused by time-varying
magnetic perturbations and halo currents flowing directly from the
plasma into the walls are important.
The relevance of a resistive wall model is directly evident for
Resistive Wall Modes (RWMs) or Vertical Displacement Events (VDEs).
However, also the linear and non-linear properties of most other
large-scale instabilities may be influenced significantly by the
interaction with currents in conducting structures near the plasma. The
understanding of halo currents arising during disruptions and VDEs,
which are a serious concern for ITER as they may lead to strong
asymmetric forces on vessel structures, could also benefit strongly from
these non-linear modeling capabilities.
Modeling the plasma dynamics and its interaction with wall currents
requires solving the magneto-hydrodynamic (MHD) equations in realistic
toroidal X-point geometry consistently coupled with a model for the
vacuum region and the resistive conducting structures. With this in
mind, the non-linear finite element MHD code JOREK [1, 2] has been
coupled [3] with the resistive wall code STARWALL [4], which allows us
to include the effects of eddy currents in 3D conducting structures in
non-linear MHD simulations.
This article summarizes the capabilities of the coupled JOREK-STARWALL
system and presents benchmark results as well as first applications to
non-linear simulations of RWMs, VDEs, disruptions triggered by massive
gas injection, and Quiescent H-Mode. As an outlook, the perspectives for
extending the model to halo currents are described.
U2 - 10.1088/1742-6596/561/1/012011
DO - 10.1088/1742-6596/561/1/012011
M3 - Article
SN - 1742-6588
VL - 561
SP - 1
EP - 10
JO - Journal of Physics: Conference Series
JF - Journal of Physics: Conference Series
IS - 1
M1 - 012011
ER -