TY - JOUR
T1 - RMS ASYMMETRY
T2 - A ROBUST METRIC OF GALAXY SHAPES IN IMAGES WITH VARIED DEPTH AND RESOLUTION.
AU - Sazonova, Elizaveta
AU - Morgan, Cameron R.
AU - Balogs, Michael
AU - Alatalo, Katherine
AU - Benavides, Jose A.
AU - Bluck, Asa
AU - Brough, Sarah
AU - Busa, Innocenza
AU - Demarco, Ricardo
AU - Donevski, Darko
AU - Figueira, Miguel
AU - Martin, Garreth
AU - Mullaney, James R.
AU - Rodriguez-Gomez, Vicente
AU - Román, Javier
AU - Rowland, Kate
N1 - Publisher Copyright:
© 2024 National University of Ireland Maynooth. All rights Reserved.
PY - 2024
Y1 - 2024
N2 - Structural disturbances, such as galaxy mergers or instabilities, are key candidates for driving galaxy evolution, so it is important to detect and quantify galaxies hosting these disturbances spanning a range of masses, environments, and cosmic times. Traditionally, this is done by quantifying the asymmetry of a galaxy as part of the concentration-asymmetry-smoothness system, ACAS, and selecting galaxies above a certain threshold as merger candidates. However, in this work, we show that ACAS, is extremely dependent on imaging properties– both resolution and depth– and thus defining a single ACAS threshold is impossible. We analyze an alternative root-mean-squared asymmetry, ARMS, and show that it is independent of noise down to the average SNR per pixel of 1. However, both metrics depend on the resolution. We argue that asymmetry is, by design, always a scale-dependent measurement, and it is essential to define an asymmetry at a given physical resolution, where the limit should be defined by the size of the smallest features one wishes to detect. We measure asymmetry of a set of z ≈ 0.1 galaxies observed with HST, HSC, and SDSS, and show that after matching the resolution of all images to 200 pc, we are able to obtain consistent ARMS,200pc measurements with all three instruments despite the vast differences in the original resolution or depth. We recommend that future studies use ARMS,xpc measurement when evaluating asymmetry, where x is defined by the physical size of the features of interest, and is kept consistent across the dataset, especially when the redshift or image properties of galaxies in the dataset vary.
AB - Structural disturbances, such as galaxy mergers or instabilities, are key candidates for driving galaxy evolution, so it is important to detect and quantify galaxies hosting these disturbances spanning a range of masses, environments, and cosmic times. Traditionally, this is done by quantifying the asymmetry of a galaxy as part of the concentration-asymmetry-smoothness system, ACAS, and selecting galaxies above a certain threshold as merger candidates. However, in this work, we show that ACAS, is extremely dependent on imaging properties– both resolution and depth– and thus defining a single ACAS threshold is impossible. We analyze an alternative root-mean-squared asymmetry, ARMS, and show that it is independent of noise down to the average SNR per pixel of 1. However, both metrics depend on the resolution. We argue that asymmetry is, by design, always a scale-dependent measurement, and it is essential to define an asymmetry at a given physical resolution, where the limit should be defined by the size of the smallest features one wishes to detect. We measure asymmetry of a set of z ≈ 0.1 galaxies observed with HST, HSC, and SDSS, and show that after matching the resolution of all images to 200 pc, we are able to obtain consistent ARMS,200pc measurements with all three instruments despite the vast differences in the original resolution or depth. We recommend that future studies use ARMS,xpc measurement when evaluating asymmetry, where x is defined by the physical size of the features of interest, and is kept consistent across the dataset, especially when the redshift or image properties of galaxies in the dataset vary.
KW - astronomy image processing (2306)
KW - Galaxy morphology (582)
KW - Galaxy structure (622)
UR - http://www.scopus.com/inward/record.url?scp=85208041328&partnerID=8YFLogxK
U2 - 10.33232/001c.123524
DO - 10.33232/001c.123524
M3 - Article
AN - SCOPUS:85208041328
SN - 2565-6120
VL - 7
JO - Open Journal of Astrophysics
JF - Open Journal of Astrophysics
ER -