Testing strong lensing subhalo detection with a cosmological simulation

He, Qiuhan; Nightingale, James; Robertson, Andrew; Amvrosiadis, Aristeidis; Cole, Shaun; Frenk, Carlos S; Massey, Richard; Li, Ran; Amorisco, Nicola C; Metcalf, R Benton; Cao, Xiaoyue; Etherington, Amy

doi:10.1093/mnras/stac2779

Testing strong lensing subhalo detection with a cosmological simulation

He, Qiuhan; Nightingale, James; Robertson, Andrew; Amvrosiadis, Aristeidis; Cole, Shaun; Frenk, Carlos S; Massey, Richard; Li, Ran; Amorisco, Nicola C; Metcalf, R Benton; Cao, Xiaoyue; Etherington, Amy

Authors

Dr Qiuhan He qiuhan.he@durham.ac.uk
Post Doctoral Research Associate

James Nightingale james.w.nightingale@durham.ac.uk
Academic Visitor

Andrew Robertson

Aristeidis Amvrosiadis aristeidis.amvrosiadis@durham.ac.uk
Post Doctoral Research Associate

Professor Shaun Cole shaun.cole@durham.ac.uk
Director of the Institute for Computational Cosmology

Professor Carlos Frenk c.s.frenk@durham.ac.uk
Professor

Professor Richard Massey r.j.massey@durham.ac.uk
Professor

Ran Li

Nicola C Amorisco

R Benton Metcalf

Xiaoyue Cao

Amy Etherington amy.etherington@durham.ac.uk
PGR Student Doctor of Philosophy

Abstract

Strong gravitational lensing offers a compelling test of the cold dark matter paradigm, as it allows for subhaloes with masses of ∼109 M⊙ and below to be detected. We test commonly-used techniques for detecting subhaloes superposed in images of strongly lensed galaxies. For the lens we take a simulated galaxy in a ∼1013 M⊙ halo grown in a high-resolution cosmological hydrodynamical simulation, which we view from two different directions. Though the resolution is high, we note the simulated galaxy still has an artificial core which adds additional complexity to the baryon dominated region. To remove particle noise, we represent the projected galaxy mass distribution by a series of Gaussian profiles which precisely capture the features of the projected galaxy. We first model the lens mass as a (broken) power-law density profile and then search for small haloes. Of the two projections, one has a regular elliptical shape, while the other has distinct deviations from an elliptical shape. For the former, the broken power-law model gives no false positives and correctly recovers the mass of the superposed small halo, but for the latter we find false positives and the inferred halo mass is overestimated by ∼4 − 5 times. We then use a more complex model in which the lens mass is decomposed into stellar and dark matter components. In this case, we show that we can capture the simulated galaxy’s complex projected structures and correctly infer the input small halo.

Citation

He, Q., Nightingale, J., Robertson, A., Amvrosiadis, A., Cole, S., Frenk, C. S., …Etherington, A. (2023). Testing strong lensing subhalo detection with a cosmological simulation. Monthly Notices of the Royal Astronomical Society, 518(1), 220-239. https://doi.org/10.1093/mnras/stac2779

Journal Article Type	Article
Publication Date	2023-01
Deposit Date	Oct 11, 2022
Publicly Available Date	Oct 11, 2022
Journal	Monthly Notices of the Royal Astronomical Society
Print ISSN	0035-8711
Electronic ISSN	1365-2966
Publisher	Royal Astronomical Society
Peer Reviewed	Peer Reviewed
Volume	518
Issue	1
Pages	220-239
DOI	https://doi.org/10.1093/mnras/stac2779
Public URL	https://durham-repository.worktribe.com/output/1189421

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Copyright Statement
This article has been accepted for publication in Monthly notices of the Royal Astronomical Society. ©: 2022 The Author(s). Published by Oxford University Press on behalf of the Royal Astronomical Society. All rights reserved.