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Hauptverfasser: Bierwage, Andreas, Lee, Wonjun, Ghim, Young-chul, Adulsiriswad, Panith, Aiba, Nobuyuki, Bong, Seungmin, Choi, Gyungjin, Falessi, Matteo, Lauber, Philipp W., Yagi, Masatoshi
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2603.24463
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author Bierwage, Andreas
Lee, Wonjun
Ghim, Young-chul
Adulsiriswad, Panith
Aiba, Nobuyuki
Bong, Seungmin
Choi, Gyungjin
Falessi, Matteo
Lauber, Philipp W.
Yagi, Masatoshi
author_facet Bierwage, Andreas
Lee, Wonjun
Ghim, Young-chul
Adulsiriswad, Panith
Aiba, Nobuyuki
Bong, Seungmin
Choi, Gyungjin
Falessi, Matteo
Lauber, Philipp W.
Yagi, Masatoshi
contents Motivated by evidence for core-edge coupling in the form of double-peaked fishbone-like low-frequency modes ($\lesssim 20\,{\rm kHz}$) in KSTAR, which exhibit synchronized Alfvénic activity both in the central core and near the plasma edge [1], we study the nonlocal response of a tokamak plasma in a visco-resistive full MHD simulation model using the code MEGA. The waves are driven by an internal "antenna" that is localized both radially and azimuthally in the poloidal $(R,z)$ plane and has a sinusoidal form $\exp(inζ- iωt)$ with Fourier mode number $n=\pm 1$ in the toroidal angle $ζ$ and fixed angular frequency $ω$ in time $t$. By flattening the safety factor profile $q(r)$ at suitable locations in the minor radius $r$, we created plateaus in the low-frequency Alfvén continua that act as wave "receivers". First, we confirm that such continuum plateaus respond with a coherent quasi-mode even when the driving antenna is located at a distant radius. Second, by varying the antenna location, we confirm the expectation of inward drive being more efficient than outward drive, which we attribute to volumetric focusing. Third, we find that the central core also responds well at frequencies below the central Alfvénic continuum plateau, which could facilitate chirping. Our results show that a core-localized low-frequency response does not necessarily require core-localized drive nor an exactly matching continuum, but may be driven from the edge and sub-resonantly. It remains to be seen to what extent the examined effects play a role in double-peaked fishbone-like activity. Other possible contributing mechanisms are discussed to motivate further study. Our analyses also elucidate the mode structure formation process, from transients to quasi- or eigenmodes, here in the realm of MHD, and to be followed by a verification study against kinetic models.
format Preprint
id arxiv_https___arxiv_org_abs_2603_24463
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Study of Low-Frequency Core-Edge Coupling in a Tokamak: II. Spatial Channeling & Focusing In Antenna-Driven MHD
Bierwage, Andreas
Lee, Wonjun
Ghim, Young-chul
Adulsiriswad, Panith
Aiba, Nobuyuki
Bong, Seungmin
Choi, Gyungjin
Falessi, Matteo
Lauber, Philipp W.
Yagi, Masatoshi
Plasma Physics
Motivated by evidence for core-edge coupling in the form of double-peaked fishbone-like low-frequency modes ($\lesssim 20\,{\rm kHz}$) in KSTAR, which exhibit synchronized Alfvénic activity both in the central core and near the plasma edge [1], we study the nonlocal response of a tokamak plasma in a visco-resistive full MHD simulation model using the code MEGA. The waves are driven by an internal "antenna" that is localized both radially and azimuthally in the poloidal $(R,z)$ plane and has a sinusoidal form $\exp(inζ- iωt)$ with Fourier mode number $n=\pm 1$ in the toroidal angle $ζ$ and fixed angular frequency $ω$ in time $t$. By flattening the safety factor profile $q(r)$ at suitable locations in the minor radius $r$, we created plateaus in the low-frequency Alfvén continua that act as wave "receivers". First, we confirm that such continuum plateaus respond with a coherent quasi-mode even when the driving antenna is located at a distant radius. Second, by varying the antenna location, we confirm the expectation of inward drive being more efficient than outward drive, which we attribute to volumetric focusing. Third, we find that the central core also responds well at frequencies below the central Alfvénic continuum plateau, which could facilitate chirping. Our results show that a core-localized low-frequency response does not necessarily require core-localized drive nor an exactly matching continuum, but may be driven from the edge and sub-resonantly. It remains to be seen to what extent the examined effects play a role in double-peaked fishbone-like activity. Other possible contributing mechanisms are discussed to motivate further study. Our analyses also elucidate the mode structure formation process, from transients to quasi- or eigenmodes, here in the realm of MHD, and to be followed by a verification study against kinetic models.
title Study of Low-Frequency Core-Edge Coupling in a Tokamak: II. Spatial Channeling & Focusing In Antenna-Driven MHD
topic Plasma Physics
url https://arxiv.org/abs/2603.24463