Escape Velocity Mass of Abell S1063

We measure the radius-velocity phase-space edge profile for Abell S1063 using galaxy redshifts from arXiv:1409.3507 and arXiv:2109.03305. Combined with a cosmological model and after accounting for interlopers and sampling effects, we infer the escape velocity profile. Using the Poisson equation, we...

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Bibliographic Details
Published inarXiv.org
Main Authors Rodriguez, Alexander, Miller, Christopher J, Halenka, Vitali, Kremin, Anthony
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 07.06.2024
Subjects
Astronomical models
Cosmology
Escape velocity
Estimates
Poisson equation
Velocity
Velocity distribution
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Summary:We measure the radius-velocity phase-space edge profile for Abell S1063 using galaxy redshifts from arXiv:1409.3507 and arXiv:2109.03305. Combined with a cosmological model and after accounting for interlopers and sampling effects, we infer the escape velocity profile. Using the Poisson equation, we then directly constrain the gravitational potential profile and find excellent agreement between three different density models. For the NFW profile, we find log\(_{10}\)(M\(_{200},{\rm crit}\))= \(15.40^{+0.06}_{-0.12}\)M\(_{\odot}\), consistent to within \(1\sigma\) of six recently published lensing masses. We argue that this consistency is due to the fact that the escape technique shares no common systematics with lensing other than radial binning. These masses are 2-4\(\sigma\) lower than estimates using X-ray data, in addition to earlier velocity dispersion estimates. We measure the 1D velocity dispersion within r\(_{200}\) to be \(\sigma_{v} = 1477^{+87}_{-99}\) km/s, which combined with our escape velocity mass, brings the dispersion for AS1063 in-line with hydrodynamic cosmological simulations for the first time.
ISSN:2331-8422