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Hauptverfasser: Erickson, Sydney, Millon, Martin, Venkatraman, Padmavathi, Li, Tian, Holloway, Philip, Marshall, Phil, Shajib, Anowar, Birrer, Simon, Huang, Xiang-Yu, Anguita, Timo, Dillmann, Steven, Khadka, Narayan, Napier, Kate, Roodman, Aaron, Collaboration, The LSST Dark Energy Science
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2511.13669
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author Erickson, Sydney
Millon, Martin
Venkatraman, Padmavathi
Li, Tian
Holloway, Philip
Marshall, Phil
Shajib, Anowar
Birrer, Simon
Huang, Xiang-Yu
Anguita, Timo
Dillmann, Steven
Khadka, Narayan
Napier, Kate
Roodman, Aaron
Collaboration, The LSST Dark Energy Science
author_facet Erickson, Sydney
Millon, Martin
Venkatraman, Padmavathi
Li, Tian
Holloway, Philip
Marshall, Phil
Shajib, Anowar
Birrer, Simon
Huang, Xiang-Yu
Anguita, Timo
Dillmann, Steven
Khadka, Narayan
Napier, Kate
Roodman, Aaron
Collaboration, The LSST Dark Energy Science
contents Strongly lensed Active Galactic Nuclei (AGN) with an observable time delay can be used to constrain the expansion history of the Universe through time-delay cosmography (TDC). As the sample of time-delay lenses grows to statistical size, with $\mathcal{O}$(1000) lensed AGN forecast to be observed by the Vera C. Rubin Observatory Legacy Survey of Space and Time (LSST), there is an emerging opportunity to use TDC as an independent probe of dark energy. To take advantage of this statistical sample, we implement a scalable hierarchical inference tool which computes the cosmological likelihood for hundreds of strong lenses simultaneously. With this new technique, we investigate the cosmological constraining power from a simulation of the full LSST sample. We start from individual lenses, and emulate the full joint hierarchical TDC analysis, including image-based modeling, time-delay measurement, velocity dispersion measurement, and external convergence prediction. We fully account for the mass-sheet and mass-anisotropy degeneracies. We assume a sample of 800 lenses, with varying levels of follow-up fidelity based on existing campaigns. With our baseline assumptions, within a flexible $w_0w_a$CDM cosmology, we simultaneously forecast a $\sim$2.5% constraint on H0 and a dark energy figure of merit (DE FOM) of 6.7. We show that by expanding the sample from 50 lenses to include an additional 750 lenses with plausible LSST time-delay measurements, we improve the forecasted DE FOM by nearly a factor of 3, demonstrating the value of incorporating this portion of the sample. We also investigate different follow-up campaign strategies, and find significant improvements in the DE FOM with additional stellar kinematics measurements and higher-precision time-delay measurements. We also demonstrate how the redshift configuration of time-delay lenses impacts constraining power in $w_0w_a$CDM.
format Preprint
id arxiv_https___arxiv_org_abs_2511_13669
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Investigating the Dark Energy Constraint from Strongly Lensed AGN at LSST-Scale
Erickson, Sydney
Millon, Martin
Venkatraman, Padmavathi
Li, Tian
Holloway, Philip
Marshall, Phil
Shajib, Anowar
Birrer, Simon
Huang, Xiang-Yu
Anguita, Timo
Dillmann, Steven
Khadka, Narayan
Napier, Kate
Roodman, Aaron
Collaboration, The LSST Dark Energy Science
Cosmology and Nongalactic Astrophysics
Strongly lensed Active Galactic Nuclei (AGN) with an observable time delay can be used to constrain the expansion history of the Universe through time-delay cosmography (TDC). As the sample of time-delay lenses grows to statistical size, with $\mathcal{O}$(1000) lensed AGN forecast to be observed by the Vera C. Rubin Observatory Legacy Survey of Space and Time (LSST), there is an emerging opportunity to use TDC as an independent probe of dark energy. To take advantage of this statistical sample, we implement a scalable hierarchical inference tool which computes the cosmological likelihood for hundreds of strong lenses simultaneously. With this new technique, we investigate the cosmological constraining power from a simulation of the full LSST sample. We start from individual lenses, and emulate the full joint hierarchical TDC analysis, including image-based modeling, time-delay measurement, velocity dispersion measurement, and external convergence prediction. We fully account for the mass-sheet and mass-anisotropy degeneracies. We assume a sample of 800 lenses, with varying levels of follow-up fidelity based on existing campaigns. With our baseline assumptions, within a flexible $w_0w_a$CDM cosmology, we simultaneously forecast a $\sim$2.5% constraint on H0 and a dark energy figure of merit (DE FOM) of 6.7. We show that by expanding the sample from 50 lenses to include an additional 750 lenses with plausible LSST time-delay measurements, we improve the forecasted DE FOM by nearly a factor of 3, demonstrating the value of incorporating this portion of the sample. We also investigate different follow-up campaign strategies, and find significant improvements in the DE FOM with additional stellar kinematics measurements and higher-precision time-delay measurements. We also demonstrate how the redshift configuration of time-delay lenses impacts constraining power in $w_0w_a$CDM.
title Investigating the Dark Energy Constraint from Strongly Lensed AGN at LSST-Scale
topic Cosmology and Nongalactic Astrophysics
url https://arxiv.org/abs/2511.13669