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Main Authors: Hansen, Erik C., Sharma, Prerana, Mahajan, Swadesh M.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.16652
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author Hansen, Erik C.
Sharma, Prerana
Mahajan, Swadesh M.
author_facet Hansen, Erik C.
Sharma, Prerana
Mahajan, Swadesh M.
contents Turbulence in the magnetized plasma is well understood to be the consequence of wave interactions. When the Hall effect is added to the minimum magnetohydrodynamics (MHD), the MHD waves become dispersive and different nonlinear interactions are expected. The emergent turbulent state will thus be expected to be different. For incompressible Hall MHD we develop a reduced model for wave-wave interactions concentrating on those processes that will lead to phase coherent modifications to the linear dispersion of a given wave. We show that these special interactions provide an amplitude-dependent contribution to the linear dispersion relation, which yields nonlinear frequency shifts. The resonance-driven frequency shifts are dominant and add damping or growth to the linear dispersion. The damping/growth rates represent the nonlinear time scales for energy redistribution and can be used in conjunction with a conjecture like the "critical balance" to estimate the energy spectral content.
format Preprint
id arxiv_https___arxiv_org_abs_2602_16652
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Nonlinear Frequency Shifts due to Phase Coherent Interactions in Incompressible Hall MHD Turbulence
Hansen, Erik C.
Sharma, Prerana
Mahajan, Swadesh M.
Plasma Physics
Turbulence in the magnetized plasma is well understood to be the consequence of wave interactions. When the Hall effect is added to the minimum magnetohydrodynamics (MHD), the MHD waves become dispersive and different nonlinear interactions are expected. The emergent turbulent state will thus be expected to be different. For incompressible Hall MHD we develop a reduced model for wave-wave interactions concentrating on those processes that will lead to phase coherent modifications to the linear dispersion of a given wave. We show that these special interactions provide an amplitude-dependent contribution to the linear dispersion relation, which yields nonlinear frequency shifts. The resonance-driven frequency shifts are dominant and add damping or growth to the linear dispersion. The damping/growth rates represent the nonlinear time scales for energy redistribution and can be used in conjunction with a conjecture like the "critical balance" to estimate the energy spectral content.
title Nonlinear Frequency Shifts due to Phase Coherent Interactions in Incompressible Hall MHD Turbulence
topic Plasma Physics
url https://arxiv.org/abs/2602.16652