Assessment of a new sub-grid model for magnetohydrodynamical turbulence. I. Magnetorotational instability
Assessment of a new sub-grid model for magnetohydrodynamical turbulence. I. Magnetorotational instability
Insufficient numerical resolution of grid-based, direct numerical simulations (DNS) hampers the development of instability-driven turbulence at small (unresolved) scales. As an alternative to DNS, sub-grid models can potentially reproduce the effects of turbulence at small scales in terms of the resolved scales, and hence can capture physical effects with less computational resources. We present a new sub-grid model, the MHD-instability-induced-turbulence (MInIT) mean-field model. MInIT is a physically motivated model based on the evolution of the turbulent (Maxwell, Reynolds, and Faraday) stress tensors and their relation with the turbulent energy densities of the magnetorotational (MRI) and parasitic instabilities, modelled with two partial differential evolution equations with stiff source terms. Their solution allows obtaining the turbulent stress tensors through the constant coefficients that link them to the energy densities. The model is assessed using data from MRI in-box DNS and applying a filtering operation to compare the filtered data with that from the model. Using the L2-norm as the metric for the comparison, we find less than one order-of-magnitude difference between the two sets of data. No dependence on filter size or length scale of unresolved scales is found, as opposed to results using the gradient model (which we also use to contrast our model) in which the L2-norm of some of the stresses increases with filter size. We conclude that MInIT can help DNS by properly capturing small-scale turbulent stresses which has potential implications on the dynamics of highly magnetized rotating compact objects, such as those formed during binary neutron star mergers.
3505–3524
Miravet-Tenés, Miquel
398b0819-ed3a-44a3-aa0c-4e912ebcbef1
Cerdá-Durán, Pablo
59f3ca65-5d00-45b9-86e9-d6a2f45cca7d
Obergaulinger, Martin
80357175-4198-4c4a-a56f-c871fda605f0
Font, José A.
51ef41b0-fdb1-4473-87f9-ebad097c5e3b
10 October 2022
Miravet-Tenés, Miquel
398b0819-ed3a-44a3-aa0c-4e912ebcbef1
Cerdá-Durán, Pablo
59f3ca65-5d00-45b9-86e9-d6a2f45cca7d
Obergaulinger, Martin
80357175-4198-4c4a-a56f-c871fda605f0
Font, José A.
51ef41b0-fdb1-4473-87f9-ebad097c5e3b
Miravet-Tenés, Miquel, Cerdá-Durán, Pablo, Obergaulinger, Martin and Font, José A.
(2022)
Assessment of a new sub-grid model for magnetohydrodynamical turbulence. I. Magnetorotational instability.
Monthly Notices Of The Royal Astronomical Society, 517 (3), .
(doi:10.1093/mnras/stac2888).
Abstract
Insufficient numerical resolution of grid-based, direct numerical simulations (DNS) hampers the development of instability-driven turbulence at small (unresolved) scales. As an alternative to DNS, sub-grid models can potentially reproduce the effects of turbulence at small scales in terms of the resolved scales, and hence can capture physical effects with less computational resources. We present a new sub-grid model, the MHD-instability-induced-turbulence (MInIT) mean-field model. MInIT is a physically motivated model based on the evolution of the turbulent (Maxwell, Reynolds, and Faraday) stress tensors and their relation with the turbulent energy densities of the magnetorotational (MRI) and parasitic instabilities, modelled with two partial differential evolution equations with stiff source terms. Their solution allows obtaining the turbulent stress tensors through the constant coefficients that link them to the energy densities. The model is assessed using data from MRI in-box DNS and applying a filtering operation to compare the filtered data with that from the model. Using the L2-norm as the metric for the comparison, we find less than one order-of-magnitude difference between the two sets of data. No dependence on filter size or length scale of unresolved scales is found, as opposed to results using the gradient model (which we also use to contrast our model) in which the L2-norm of some of the stresses increases with filter size. We conclude that MInIT can help DNS by properly capturing small-scale turbulent stresses which has potential implications on the dynamics of highly magnetized rotating compact objects, such as those formed during binary neutron star mergers.
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Published date: 10 October 2022
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Local EPrints ID: 503234
URI: http://eprints.soton.ac.uk/id/eprint/503234
ISSN: 1365-2966
PURE UUID: 41e88aa4-0756-446a-8da2-edbc02d53238
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Date deposited: 24 Jul 2025 17:02
Last modified: 25 Jul 2025 02:15
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Author:
Miquel Miravet-Tenés
Author:
Pablo Cerdá-Durán
Author:
Martin Obergaulinger
Author:
José A. Font
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