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Published June 15, 2022 | Accepted Version + Published
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Simulating magnetized neutron stars with discontinuous Galerkin methods

Deppe, Nils ORCID icon
Hébert, François ORCID icon
Kidder, Lawrence E. ORCID icon
Throwe, William ORCID icon
Anantpurkar, Isha
Armaza, Cristóbal
Bonilla, Gabriel S. ORCID icon
Boyle, Michael ORCID icon
Chaudhary, Himanshu ORCID icon
Duez, Matthew D. ORCID icon
Vu, Nils L. ORCID icon
Foucart, François ORCID icon
Giesler, Matthew ORCID icon
Guo, Jason S. ORCID icon
Kim, Yoonsoo
Kumar, Prayush
Legred, Isaac ORCID icon
Li, Dongjun
Lovelace, Geoffrey ORCID icon
Ma, Sizheng ORCID icon
Macedo, Alexandra
Melchor, Denyz
Morales, Marlo
Moxon, Jordan ORCID icon
Nelli, Kyle C. ORCID icon
O'Shea, Eamonn ORCID icon
Pfeiffer, Harald P. ORCID icon
Ramirez, Teresita
Rüter, Hannes R.
Sanchez, Jennifer
Scheel, Mark A. ORCID icon
Thomas, Sierra
Vieira, Daniel ORCID icon
Wittek, Nikolas A. ORCID icon
Wlodarczyk, Tom
Teukolsky, Saul A. ORCID icon
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Abstract

Discontinuous Galerkin methods are popular because they can achieve high order where the solution is smooth, because they can capture shocks while needing only nearest-neighbor communication, and because they are relatively easy to formulate on complex meshes. We perform a detailed comparison of various limiting strategies presented in the literature applied to the equations of general relativistic magnetohydrodynamics. We compare the standard minmod/ΛΠᴺ limiter, the hierarchical limiter of Krivodonova, the simple WENO limiter, the HWENO limiter, and a discontinuous Galerkin-finite-difference hybrid method. The ultimate goal is to understand what limiting strategies are able to robustly simulate magnetized Tolman-Oppenheimer-Volkoff stars without any fine-tuning of parameters. Among the limiters explored here, the only limiting strategy we can endorse is a discontinuous Galerkin-finite-difference hybrid method.

Additional Information

© 2022 American Physical Society. (Received 29 September 2021; revised 6 May 2022; accepted 1 June 2022; published 27 June 2022) Charm++/Converse [83] was developed by the Parallel Programming Laboratory in the Department of Computer Science at the University of Illinois at Urbana-Champaign. The figures in this article were produced with matplotlib [84,85], tikz [86] and paraview [87,88]. Computations were performed with the Wheeler cluster at Caltech. This work was supported in part by the Sherman Fairchild Foundation and by NSF Grants No. PHY-2011961, No. PHY-2011968, and No. OAC-1931266 at Caltech, and NSF Grants No. PHY- 1912081 and No. OAC-1931280 at Cornell. P. K. acknowledges support of the Department of Atomic Energy, Government of India, under Project No. RTI4001, and by the Ashok and Gita Vaish Early Career Faculty Fellowship at the International Centre for Theoretical Sciences. M. D. acknowledges support from the NSF through Grant No. PHY-2110287. F. F. acknowledges support from the DOE through Grant No. DE-SC0020435, from NASA through Grant No. 80NSSC18K0565 and from the NSF through Grant No. PHY-1806278. G. L. is pleased to acknowledge support from the NSF through Grants No. PHY-1654359 and No. AST-1559694 and from Nicholas and Lee Begovich and the Dan Black Family Trust. H. R. R. acknowledges support from the Fundação para a Ciência e Tecnologia (FCT) within the Projects No. UID/04564/2021, No. UIDB/04564/2020, No. UIDP/04564/2020 and No. EXPL/FIS-AST/0735/2021.

Attached Files

Published - PhysRevD.105.123031.pdf

Accepted Version - 2109.12033.pdf

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August 20, 2023
Modified:
October 23, 2023