A numerical stability analysis for the Einstein-Vlasov system

Sebastian Günther; Jacob Körner; Timo Lebeda; Bastian Pötzl; Gerhard Rein; Christopher Straub; Jörg Weber

doi:10.1088/1361-6382/abcbdf

A numerical stability analysis for the Einstein-Vlasov system

Sebastian Günther, Jacob Körner, Timo Lebeda, Bastian Pötzl, Gerhard Rein, Christopher Straub, Jörg Weber

Mathematics (Faculty of Sciences)

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate stability issues for steady states of the spherically symmetric Einstein-Vlasov system numerically in Schwarzschild, maximal areal, and Eddington-Finkelstein coordinates. Across all coordinate systems we confirm the conjecture that the first binding energy maximum along a one-parameter family of steady states signals the onset of instability. Beyond this maximum perturbed solutions either collapse to a black hole, form heteroclinic orbits, or eventually fully disperse. Contrary to earlier research, we find that a negative binding energy does not necessarily correspond to fully dispersing solutions. We also comment on the so-called turning point principle from the viewpoint of our numerical results. The physical reliability of the latter is strengthened by obtaining consistent results in the three different coordinate systems and by the systematic use of dynamically accessible perturbations.

Original language	English
Article number	035003
Journal	Classical and Quantum Gravity
Volume	38
Issue number	3
DOIs	https://doi.org/10.1088/1361-6382/abcbdf
Publication status	Published - 2021

Subject classification (UKÄ)

Mathematical Analysis

Free keywords

binding energy
black hole
collapse
Einstein-Vlasov
heteroclinic orbit
stability
turning point

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10.1088/1361-6382/abcbdf

Cite this

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title = "A numerical stability analysis for the Einstein-Vlasov system",

abstract = "We investigate stability issues for steady states of the spherically symmetric Einstein-Vlasov system numerically in Schwarzschild, maximal areal, and Eddington-Finkelstein coordinates. Across all coordinate systems we confirm the conjecture that the first binding energy maximum along a one-parameter family of steady states signals the onset of instability. Beyond this maximum perturbed solutions either collapse to a black hole, form heteroclinic orbits, or eventually fully disperse. Contrary to earlier research, we find that a negative binding energy does not necessarily correspond to fully dispersing solutions. We also comment on the so-called turning point principle from the viewpoint of our numerical results. The physical reliability of the latter is strengthened by obtaining consistent results in the three different coordinate systems and by the systematic use of dynamically accessible perturbations. ",

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doi = "10.1088/1361-6382/abcbdf",

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TY - JOUR

T1 - A numerical stability analysis for the Einstein-Vlasov system

AU - Günther, Sebastian

AU - Körner, Jacob

AU - Lebeda, Timo

AU - Pötzl, Bastian

AU - Rein, Gerhard

AU - Straub, Christopher

AU - Weber, Jörg

PY - 2021

Y1 - 2021

N2 - We investigate stability issues for steady states of the spherically symmetric Einstein-Vlasov system numerically in Schwarzschild, maximal areal, and Eddington-Finkelstein coordinates. Across all coordinate systems we confirm the conjecture that the first binding energy maximum along a one-parameter family of steady states signals the onset of instability. Beyond this maximum perturbed solutions either collapse to a black hole, form heteroclinic orbits, or eventually fully disperse. Contrary to earlier research, we find that a negative binding energy does not necessarily correspond to fully dispersing solutions. We also comment on the so-called turning point principle from the viewpoint of our numerical results. The physical reliability of the latter is strengthened by obtaining consistent results in the three different coordinate systems and by the systematic use of dynamically accessible perturbations.

AB - We investigate stability issues for steady states of the spherically symmetric Einstein-Vlasov system numerically in Schwarzschild, maximal areal, and Eddington-Finkelstein coordinates. Across all coordinate systems we confirm the conjecture that the first binding energy maximum along a one-parameter family of steady states signals the onset of instability. Beyond this maximum perturbed solutions either collapse to a black hole, form heteroclinic orbits, or eventually fully disperse. Contrary to earlier research, we find that a negative binding energy does not necessarily correspond to fully dispersing solutions. We also comment on the so-called turning point principle from the viewpoint of our numerical results. The physical reliability of the latter is strengthened by obtaining consistent results in the three different coordinate systems and by the systematic use of dynamically accessible perturbations.

KW - binding energy

KW - black hole

KW - collapse

KW - Einstein-Vlasov

KW - heteroclinic orbit

KW - stability

KW - turning point

U2 - 10.1088/1361-6382/abcbdf

DO - 10.1088/1361-6382/abcbdf

M3 - Article

AN - SCOPUS:85099042417

SN - 0264-9381

VL - 38

JO - Classical and Quantum Gravity

JF - Classical and Quantum Gravity

IS - 3

M1 - 035003

ER -

A numerical stability analysis for the Einstein-Vlasov system

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