IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles

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IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles. / Birrer, S.; Shajib, A. J.; Galan, A.; Millon, M.; Treu, T.; Agnello, A.; Auger, M.; Chen, G. C. -F.; Christensen, L.; Collett, T.; Courbin, F.; Fassnacht, C. D.; Koopmans, L. V. E.; Marshall, P. J.; Park, J. -W.; Rusu, C. E.; Sluse, D.; Spiniello, C.; Suyu, S. H.; Wagner-Carena, S.; Wong, K. C.; Barnabe, M.; Bolton, A. S.; Czoske, O.; Ding, X.; Frieman, J. A.; Van de Vyvere, L.

I: Astronomy & Astrophysics, Bind 643, A165, 20.11.2020.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Birrer, S, Shajib, AJ, Galan, A, Millon, M, Treu, T, Agnello, A, Auger, M, Chen, GC-F, Christensen, L, Collett, T, Courbin, F, Fassnacht, CD, Koopmans, LVE, Marshall, PJ, Park, J-W, Rusu, CE, Sluse, D, Spiniello, C, Suyu, SH, Wagner-Carena, S, Wong, KC, Barnabe, M, Bolton, AS, Czoske, O, Ding, X, Frieman, JA & Van de Vyvere, L 2020, 'IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles', Astronomy & Astrophysics, bind 643, A165. https://doi.org/10.1051/0004-6361/202038861

APA

Birrer, S., Shajib, A. J., Galan, A., Millon, M., Treu, T., Agnello, A., Auger, M., Chen, G. C. -F., Christensen, L., Collett, T., Courbin, F., Fassnacht, C. D., Koopmans, L. V. E., Marshall, P. J., Park, J. -W., Rusu, C. E., Sluse, D., Spiniello, C., Suyu, S. H., ... Van de Vyvere, L. (2020). IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles. Astronomy & Astrophysics, 643, [A165]. https://doi.org/10.1051/0004-6361/202038861

Vancouver

Birrer S, Shajib AJ, Galan A, Millon M, Treu T, Agnello A o.a. IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles. Astronomy & Astrophysics. 2020 nov. 20;643. A165. https://doi.org/10.1051/0004-6361/202038861

Author

Birrer, S. ; Shajib, A. J. ; Galan, A. ; Millon, M. ; Treu, T. ; Agnello, A. ; Auger, M. ; Chen, G. C. -F. ; Christensen, L. ; Collett, T. ; Courbin, F. ; Fassnacht, C. D. ; Koopmans, L. V. E. ; Marshall, P. J. ; Park, J. -W. ; Rusu, C. E. ; Sluse, D. ; Spiniello, C. ; Suyu, S. H. ; Wagner-Carena, S. ; Wong, K. C. ; Barnabe, M. ; Bolton, A. S. ; Czoske, O. ; Ding, X. ; Frieman, J. A. ; Van de Vyvere, L. / IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles. I: Astronomy & Astrophysics. 2020 ; Bind 643.

Bibtex

@article{b2a99967cab3445d836c491a7d969cfe,
title = "IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles",
abstract = "The H0LiCOWcollaboration inferred via strong gravitational lensing time delays a Hubble constant value of H0 = 73 :3+1:7 1:8 km s 1 Mpc 1, describing deflector mass density profiles by either a power-law or stars (constant mass-to-light ratio) plus standard dark matter halos. The mass-sheet transform (MST) that leaves the lensing observables unchanged is considered the dominant source of residual uncertainty in H0. We quantify any potential e ffect of the MST with a flexible family of mass models, which directly encodes it, and they are hence maximally degenerate with H0. Our calculation is based on a new hierarchical Bayesian approach in which the MST is only constrained by stellar kinematics. The approach is validated on mock lenses, which are generated from hydrodynamic simulations. We first applied the inference to the TDCOSMO sample of seven lenses, six of which are from H0LiCOW, and measured H0 = 74 :5+5:6 6:1 km s 1 Mpc 1. Secondly, in order to further constrain the deflector mass density profiles, we added imaging and spectroscopy for a set of 33 strong gravitational lenses from the Sloan Lens ACS (SLACS) sample. For nine of the 33 SLAC lenses, we used resolved kinematics to constrain the stellar anisotropy. From the joint hierarchical analysis of the TDCOSMO +SLACS sample, we measured H0 = 67 :4+4:1 3:2 km s 1 Mpc 1. This measurement assumes that the TDCOSMO and SLACS galaxies are drawn from the same parent population. The blind H0LiCOW, TDCOSMO-only and TDCOSMO +SLACS analyses are in mutual statistical agreement. The TDCOSMO +SLACS analysis prefers marginally shallower mass profiles than H0LiCOW or TDCOSMO-only. Without relying on the form of the mass density profile used by H0LiCOW, we achieve a similar to 5% measurement of H0. While our new hierarchical analysis does not statistically invalidate the mass profile assumptions by H0LiCOW - and thus the H0 measurement relying on them - it demonstrates the importance of understanding the mass density profile of elliptical galaxies. The uncertainties on H0 derived in this paper can be reduced by physical or observational priors on the form of the mass profile, or by additional data.",
keywords = "gravitational lensing: strong, galaxies: general, galaxies: kinematics and dynamics, distance scale, cosmological parameters, cosmology: observations, LENS ACS SURVEY, LINE-OF-SIGHT, GRAVITATIONAL LENS, 2-DIMENSIONAL KINEMATICS, INTERNAL STRUCTURE, SLACS LENSES, VELOCITY DISPERSIONS, ELLIPTIC GALAXIES, DYNAMICAL MODELS, IMAGED QUASAR",
author = "S. Birrer and Shajib, {A. J.} and A. Galan and M. Millon and T. Treu and A. Agnello and M. Auger and Chen, {G. C. -F.} and L. Christensen and T. Collett and F. Courbin and Fassnacht, {C. D.} and Koopmans, {L. V. E.} and Marshall, {P. J.} and Park, {J. -W.} and Rusu, {C. E.} and D. Sluse and C. Spiniello and Suyu, {S. H.} and S. Wagner-Carena and Wong, {K. C.} and M. Barnabe and Bolton, {A. S.} and O. Czoske and X. Ding and Frieman, {J. A.} and {Van de Vyvere}, L.",
year = "2020",
month = nov,
day = "20",
doi = "10.1051/0004-6361/202038861",
language = "English",
volume = "643",
journal = "Astronomy & Astrophysics",
issn = "0004-6361",
publisher = "E D P Sciences",

}

RIS

TY - JOUR

T1 - IV. Hierarchical time-delay cosmography - joint inference of the Hubble constant and galaxy density profiles

AU - Birrer, S.

AU - Shajib, A. J.

AU - Galan, A.

AU - Millon, M.

AU - Treu, T.

AU - Agnello, A.

AU - Auger, M.

AU - Chen, G. C. -F.

AU - Christensen, L.

AU - Collett, T.

AU - Courbin, F.

AU - Fassnacht, C. D.

AU - Koopmans, L. V. E.

AU - Marshall, P. J.

AU - Park, J. -W.

AU - Rusu, C. E.

AU - Sluse, D.

AU - Spiniello, C.

AU - Suyu, S. H.

AU - Wagner-Carena, S.

AU - Wong, K. C.

AU - Barnabe, M.

AU - Bolton, A. S.

AU - Czoske, O.

AU - Ding, X.

AU - Frieman, J. A.

AU - Van de Vyvere, L.

PY - 2020/11/20

Y1 - 2020/11/20

N2 - The H0LiCOWcollaboration inferred via strong gravitational lensing time delays a Hubble constant value of H0 = 73 :3+1:7 1:8 km s 1 Mpc 1, describing deflector mass density profiles by either a power-law or stars (constant mass-to-light ratio) plus standard dark matter halos. The mass-sheet transform (MST) that leaves the lensing observables unchanged is considered the dominant source of residual uncertainty in H0. We quantify any potential e ffect of the MST with a flexible family of mass models, which directly encodes it, and they are hence maximally degenerate with H0. Our calculation is based on a new hierarchical Bayesian approach in which the MST is only constrained by stellar kinematics. The approach is validated on mock lenses, which are generated from hydrodynamic simulations. We first applied the inference to the TDCOSMO sample of seven lenses, six of which are from H0LiCOW, and measured H0 = 74 :5+5:6 6:1 km s 1 Mpc 1. Secondly, in order to further constrain the deflector mass density profiles, we added imaging and spectroscopy for a set of 33 strong gravitational lenses from the Sloan Lens ACS (SLACS) sample. For nine of the 33 SLAC lenses, we used resolved kinematics to constrain the stellar anisotropy. From the joint hierarchical analysis of the TDCOSMO +SLACS sample, we measured H0 = 67 :4+4:1 3:2 km s 1 Mpc 1. This measurement assumes that the TDCOSMO and SLACS galaxies are drawn from the same parent population. The blind H0LiCOW, TDCOSMO-only and TDCOSMO +SLACS analyses are in mutual statistical agreement. The TDCOSMO +SLACS analysis prefers marginally shallower mass profiles than H0LiCOW or TDCOSMO-only. Without relying on the form of the mass density profile used by H0LiCOW, we achieve a similar to 5% measurement of H0. While our new hierarchical analysis does not statistically invalidate the mass profile assumptions by H0LiCOW - and thus the H0 measurement relying on them - it demonstrates the importance of understanding the mass density profile of elliptical galaxies. The uncertainties on H0 derived in this paper can be reduced by physical or observational priors on the form of the mass profile, or by additional data.

AB - The H0LiCOWcollaboration inferred via strong gravitational lensing time delays a Hubble constant value of H0 = 73 :3+1:7 1:8 km s 1 Mpc 1, describing deflector mass density profiles by either a power-law or stars (constant mass-to-light ratio) plus standard dark matter halos. The mass-sheet transform (MST) that leaves the lensing observables unchanged is considered the dominant source of residual uncertainty in H0. We quantify any potential e ffect of the MST with a flexible family of mass models, which directly encodes it, and they are hence maximally degenerate with H0. Our calculation is based on a new hierarchical Bayesian approach in which the MST is only constrained by stellar kinematics. The approach is validated on mock lenses, which are generated from hydrodynamic simulations. We first applied the inference to the TDCOSMO sample of seven lenses, six of which are from H0LiCOW, and measured H0 = 74 :5+5:6 6:1 km s 1 Mpc 1. Secondly, in order to further constrain the deflector mass density profiles, we added imaging and spectroscopy for a set of 33 strong gravitational lenses from the Sloan Lens ACS (SLACS) sample. For nine of the 33 SLAC lenses, we used resolved kinematics to constrain the stellar anisotropy. From the joint hierarchical analysis of the TDCOSMO +SLACS sample, we measured H0 = 67 :4+4:1 3:2 km s 1 Mpc 1. This measurement assumes that the TDCOSMO and SLACS galaxies are drawn from the same parent population. The blind H0LiCOW, TDCOSMO-only and TDCOSMO +SLACS analyses are in mutual statistical agreement. The TDCOSMO +SLACS analysis prefers marginally shallower mass profiles than H0LiCOW or TDCOSMO-only. Without relying on the form of the mass density profile used by H0LiCOW, we achieve a similar to 5% measurement of H0. While our new hierarchical analysis does not statistically invalidate the mass profile assumptions by H0LiCOW - and thus the H0 measurement relying on them - it demonstrates the importance of understanding the mass density profile of elliptical galaxies. The uncertainties on H0 derived in this paper can be reduced by physical or observational priors on the form of the mass profile, or by additional data.

KW - gravitational lensing: strong

KW - galaxies: general

KW - galaxies: kinematics and dynamics

KW - distance scale

KW - cosmological parameters

KW - cosmology: observations

KW - LENS ACS SURVEY

KW - LINE-OF-SIGHT

KW - GRAVITATIONAL LENS

KW - 2-DIMENSIONAL KINEMATICS

KW - INTERNAL STRUCTURE

KW - SLACS LENSES

KW - VELOCITY DISPERSIONS

KW - ELLIPTIC GALAXIES

KW - DYNAMICAL MODELS

KW - IMAGED QUASAR

U2 - 10.1051/0004-6361/202038861

DO - 10.1051/0004-6361/202038861

M3 - Journal article

VL - 643

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

SN - 0004-6361

M1 - A165

ER -

ID: 253236902