<i>Euclid</i>preparation

Guglielmo, V.; Saglia, R.; Castander, F. J.; Galametz, A.; Paltani, S.; Bender, Ralf; Bolzonella, M.; Capak, P.; Ilbert, O.; Masters, D. C.; Stern, Daniel; Andreon, S.; Auricchio, N.; Balaguera-Antolínez, A.; Baldi, Marco; Bardelli, S.; Biviano, A.; Bodendorf, C.; Bonino, D.; Bozzo, E.; Branchini, E.; Brau-Nogué, Sylvie; Brescia, M.; Burigana, C.; Cabanac, R.; Camera, Stefano; Capobianco, V.; Cappi, A.; Carbone, C.; Carretero, J.; Carvalho, C. S.; Casas, R.; Casas, S.; Castellano, M.; Castignani, G.; Cavuoti, S.; Cimatti, A.; Clédassou, R.; Colodro-Conde, Carlos; Congedo, G.; Conselice, Christopher J.; Conversi, L.; Copin, Y.; Corcione, L.; Costille, A.; Coupon, J.; Courtois, H. M.; Cropper, Mark; Silva, Antônio da; Torre, S. de la; Ferdinando, D. Di; Dubath, F.; Duncan, C. A. J.; Dupac, X.; Dusini, S.; Fabricius, Maximilian; Farrens, S.; Ferreira, Pedro G.; Fotopoulou, S.; Frailis, M.; Franceschi, E.; Fumana, M.; Galeotta, S.; Garilli, B.; Gillis, B.; Giocoli, Carlo; Gozaliasl, G.; Graciá-Carpio, J.; Grupp, F.; Guzzo, L.; Hildebrandt, Helmut; Hoekstra, Henk; Hormuth, F.; Israel, Holger; Jahnke, K.; Keihänen, E.; Kermiche, S.; Kilbinger, M.; Kirkpatrick, C. C.; Kitching, Thomas D.; Kubik, B.; Kunz, M.; Kurki-Suonio, H.; Laureijs, R. J.; Ligori, S.; Lilje, P. B.; Lloro, I.; Maino, D.; Maiorano, E.; Maraston, Claudia; Marggraf, O.; Martinet, N.; Marulli, F.; Massey, Richard; Maurogordato, S.; Medinaceli, E.; Mei, S.; Meneghetti, M.; Metcalf, R. Benton; Meylan, G.; Moresco, M.; Moscardini, L.; Munari, E.; Nakajima, Reiko; Neissner, C.; Niemi, S. M.; Nucita, A. A.; Aranda, C. Padilla; Pasian, F.; Patrizii, L.; Pocino, A.; Poncet, M.; Pozzetti, L.; Raison, F.; Renzi, A.; Rhodes, Jason; Riccio, G.; Romelli, E.; Roncarelli, M.; Rossetti, E.; Sánchez, Ariel G.; Sapone, Domenico; Schneider, Peter; Scottez, V.; Secroun, A.; Serrano, S.; Sirignano, C.; Sirri, G.; Sureau, F.; Tallada-Crespí, P.; Tavagnacco, D.; Taylor, Andy; Tenti, M.; Tereno, I.; Toledo-Moreo, R.; Torradeflot, F.; Tramacere, A.; Valenziano, L.; Vassallo, T.; Wang, Y.; Welikala, N.; Wetzstein, Michael E.; Whittaker, L.; Zacchei, A.; Zamorani, G.; Zoubian, J.; Zucca, E.

doi:10.1051/0004-6361/202038334

Cited by 16 publications

(1 citation statement)

References 43 publications

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“…The Complete Calibration of the Color-Redshift Relation (C3R2) survey is a multi-institution, multi-instrument survey that aims to map the empirical relation of galaxy color to redshift up to I AB ∼ 24.5 mag. The C3R2 has released several data (e.g., Masters et al 2017Masters et al , 2019Collaboration et al 2020;Stanford et al 2021) and about 5000 highly reliable redshifts. In addition, we also include the unpublished (e.g., UCR DEIMOS Survey) spectroscopic redshifts compiled by N. P. Hathi (2018, private communication).…”

Section: Redshift Datamentioning

confidence: 99%

Revisiting Galaxy Evolution in Morphology in the Cosmic Evolution Survey Field (COSMOS-ReGEM). I. Merging Galaxies

Ren,

Li,

Liu

et al. 2023

ApJ

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We revisit the evolution of galaxy morphology in the Cosmic Evolution Survey field over the redshift range 0.2 ≤ z ≤ 1, using a large and complete sample of 33,605 galaxies with a stellar mass of log(M */M ⊙) > 9.5 with significantly improved redshifts and comprehensive nonparametric morphological parameters. Our sample has 13,881 (∼41.3%) galaxies with reliable spectroscopic redshifts and more accurate photometric redshifts with a σ NMAD ∼ 0.005. This paper is the first in a series that investigates merging galaxies and their properties. We identify 3594 major merging galaxies through visual inspection and find 1737 massive galaxy pairs with log(M */M ⊙) >10.1. Among the family of nonparametric morphological parameters including C, A, S, Gini, M 20, A O, and D O, we find that the outer asymmetry parameter A O and the second-order momentum parameter M 20 are the best tracers of merging features compared to other combinations. Hence, we propose a criterion for selecting candidates of violently star-forming mergers: M 20 > − 3A O + 3 at 0.2 < z < 0.6 and M 20 > − 6A O + 3.7 at 0.6 < z < 1.0. Furthermore, we show that both the visual merger sample and the pair sample exhibit a similar evolution in the merger rate at z < 1, with R ∼ ( 1 + z ) 1.79 ± 0.13 for the visual merger sample and R ∼ ( 1 + z ) 2.02 ± 0.42 for the pair sample. The visual merger sample has a specific star formation rate that is about 0.16 dex higher than that of nonmerger galaxies, whereas no significant star formation excess is observed in the pair sample. This suggests that the effects of mergers on star formation differ at different merger stages.

show abstract

Section: Redshift Datamentioning

confidence: 99%

Revisiting Galaxy Evolution in Morphology in the Cosmic Evolution Survey Field (COSMOS-ReGEM). I. Merging Galaxies

Ren,

Li,

Liu

et al. 2023

ApJ

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show abstract

Cosmology intertwined: A review of the particle physics, astrophysics, and cosmology associated with the cosmological tensions and anomalies

Abdalla

Abellán

Aboubrahim

et al. 2022

Journal of High Energy Astrophysics

656

312

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KiDS-1000 catalogue: Redshift distributions and their calibration

Hildebrandt¹,

Busch²,

Wright³

et al. 2021

A&A

Self Cite

119

138

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We present redshift distribution estimates of galaxies selected from the fourth data release of the Kilo-Degree Survey over an area of ∼1000 deg2 (KiDS-1000). These redshift distributions represent one of the crucial ingredients for weak gravitational lensing measurements with the KiDS-1000 data. The primary estimate is based on deep spectroscopic reference catalogues that are re-weighted with the help of a self-organising map (SOM) to closely resemble the KiDS-1000 sources, split into five tomographic redshift bins in the photometric redshift range 0.1 < zB ≤ 1.2. Sources are selected such that they only occupy that volume of nine-dimensional magnitude-space that is also covered by the reference samples (‘gold’ selection). Residual biases in the mean redshifts determined from this calibration are estimated from mock catalogues to be ≲0.01 for all five bins with uncertainties of ∼0.01. This primary SOM estimate of the KiDS-1000 redshift distributions is complemented with an independent clustering redshift approach. After validation of the clustering-z on the same mock catalogues and a careful assessment of systematic errors, we find no significant bias of the SOM redshift distributions with respect to the clustering-z measurements. The SOM redshift distributions re-calibrated by the clustering-z represent an alternative calibration of the redshift distributions with only slightly larger uncertainties in the mean redshifts of ∼0.01 − 0.02 to be used in KiDS-1000 cosmological weak lensing analyses. As this includes the SOM uncertainty, clustering-z are shown to be fully competitive on KiDS-1000 data.

show abstract

Euclidpreparation

Cited by 16 publications

References 43 publications

Revisiting Galaxy Evolution in Morphology in the Cosmic Evolution Survey Field (COSMOS-ReGEM). I. Merging Galaxies

Revisiting Galaxy Evolution in Morphology in the Cosmic Evolution Survey Field (COSMOS-ReGEM). I. Merging Galaxies

Cosmology intertwined: A review of the particle physics, astrophysics, and cosmology associated with the cosmological tensions and anomalies

KiDS-1000 catalogue: Redshift distributions and their calibration

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