Application of local discontinuous Galerkin method to Einstein equations

Cao, Zhoujian; Fu, Pei; Ji, Liu; Xia, Yun‐Jie

doi:10.1142/s0218271819500147

Cited by 10 publications

(10 citation statements)

References 30 publications

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“…Other notable but non-public codes include BAM (Bruegmann et al, 2008;Marronetti et al, 2007), AMSS-NCKU (Galaviz et al, 2010), PAMR/AMRD and HAD (East et al, 2012;Neilsen et al, 2007). Codes such as SPeC (Pfeiffer et al, 2003) and bamps (Hilditch et al, 2016) implement the generalised harmonic formulation of the Einstein equations using a pseudospectral method, and discontinuous Galerkin methods are used in SpECTRE (https://spectre-code.org) (Deppe et al, 2021;Kidder & others, 2017) (see also (Cao et al, 2018)). NRPy (http: //astro.phys.wvu.edu/bhathome) (Ruchlin et al, 2018) is a code aimed for use on non-HPC systems, which generate C code from Python, and uses adapted coordinate systems to minimise computational costs.…”

Section: Statement Of Needmentioning

confidence: 99%

GRChombo: An adaptable numerical relativity code for fundamental physics

Andrade¹,

Saló²,

Aurrekoetxea³

et al. 2021

JOSS

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Section: Statement Of Needmentioning

confidence: 99%

GRChombo: An adaptable numerical relativity code for fundamental physics

Andrade¹,

Saló²,

Aurrekoetxea³

et al. 2021

JOSS

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“…After the initial data are ready, we come to the evolution equations [735]. There are well developed finite element methods for Hamilton-Jacobi-like equations [736]…”

Section: Finite Element Numerical Relativitymentioning

confidence: 99%

“…where the unknown variables u μ and the related A μ ν (u σ ) and S μ (u σ ) are given in ref. [735]. Eq.…”

Section: Finite Element Numerical Relativitymentioning

confidence: 99%

The Gravitational-wave physics II: Progress

Bian

Cai

Cao

et al. 2021

Sci. China Phys. Mech. Astron.

Self Cite

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It has been a half-decade since the first direct detection of gravitational waves, which signifies the coming of the era of the gravitational-wave astronomy and gravitational-wave cosmology. The increasing number of the detected gravitational-wave events has revealed the promising capability of constraining various aspects of cosmology, astronomy, and gravity. Due to the limited space in this review article, we will briefly summarize the recent progress over the past five years, but with a special focus on some of our own work for the Key Project "Physics associated with the gravitational waves" supported by the National Natural Science Foundation of China. In particular, (1) we have presented the mechanism of the gravitational-wave production during some physical processes of the early Universe, such as inflation, preheating and phase transition, and the cosmological implications of gravitational-wave measurements; (2) we have put constraints on the neutron star maximum mass according to GW170817 observations; (3) we have developed a numerical relativity algorithm based on the finite element method and a waveform model for the binary black hole coalescence along an eccentric orbit.

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“…Alternatives are problem-adapted coordinate systems, e.g. NRPy+ [68] or discontinuous Galerkin methods as in SpECTRE [69,70] (see also [71,72]). A brief overview of the history of NR codes can be found in [73].…”

Section: Introductionmentioning

confidence: 99%

Lessons for adaptive mesh refinement in numerical relativity

Radia,

Sperhake,

Drew

et al. 2021

Preprint

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We demonstrate the flexibility and utility of the Berger-Rigoutsos Adaptive Mesh Refinement (AMR) algorithm used in the open-source numerical relativity code GRChombo for generating gravitational waveforms from binary black-hole inspirals, and for studying other problems involving non-trivial matter configurations. We show that GRChombo can produce high quality binary black-hole waveforms through a code comparison with the established numerical relativity code Lean. We also discuss some of the technical challenges involved in making use of full AMR (as opposed to, e.g. moving box mesh refinement), including the numerical effects caused by using various refinement criteria when regridding. We suggest several "rules of thumb" for when to use different tagging criteria for simulating a variety of physical phenomena. We demonstrate the use of these different criteria through example evolutions of a scalar field theory. Finally, we also review the current status and general capabilities of GRChombo.

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Application of local discontinuous Galerkin method to Einstein equations

Cited by 10 publications

References 30 publications

GRChombo: An adaptable numerical relativity code for fundamental physics

GRChombo: An adaptable numerical relativity code for fundamental physics

The Gravitational-wave physics II: Progress

Lessons for adaptive mesh refinement in numerical relativity

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