TY - JOUR
T1 - Euclid preparation
T2 - XII. Optimizing the photometric sample of the Euclid survey for galaxy clustering and galaxy-galaxy lensing analyses
AU - Euclid Collaboration
AU - Pocino, A.
AU - Tutusaus, I.
AU - Castander, F. J.
AU - Fosalba, P.
AU - Crocce, M.
AU - Porredon, A.
AU - Camera, S.
AU - Cardone, V.
AU - Casas, S.
AU - Kitching, T.
AU - Lacasa, F.
AU - Martinelli, M.
AU - Sakr, Z.
AU - Andreon, S.
AU - Auricchio, N.
AU - Baccigalupi, C.
AU - Balaguera-Antolínez, A.
AU - Baldi, M.
AU - Balestra, A.
AU - Bardelli, S.
AU - Bender, R.
AU - Biviano, A.
AU - Bodendorf, C.
AU - Bonino, D.
AU - Boucaud, A.
AU - Bozzo, E.
AU - Branchini, E.
AU - Brescia, M.
AU - Brinchmann, J.
AU - Burigana, C.
AU - Cabanac, R.
AU - Capobianco, V.
AU - Cappi, A.
AU - Carvalho, C. S.
AU - Castellano, M.
AU - Castignani, G.
AU - Cavuoti, S.
AU - Cimatti, A.
AU - Cledassou, R.
AU - Colodro-Conde, C.
AU - Congedo, G.
AU - Conselice, C. J.
AU - Conversi, L.
AU - Copin, Y.
AU - Corcione, L.
AU - Costille, A.
AU - Coupon, J.
AU - Courtois, H. M.
AU - Cropper, M.
AU - Nichol, R. C.
N1 - Funding Information:
Acknowledgements. A. Pocino acknowledges financial support from the Sec-retaria d’Universitats i Recerca del Departament d’Empresa i Coneixement de la Generalitat de Catalunya with additional funding from the European FEDER/ERF funds, L’FSE inverteix en el teu futur. I. Tutusaus acknowledges support from the Spanish Ministry of Science, Innovation and Universities through grant ESP2017-89838, and the H2020 programme of the European Commission through grant 776247. S. Camera acknowledges support from the ‘Departments of Excellence 2018-2022’ Grant awarded by the Italian Ministry of Education, University and Research (Miur) L. 232/2016. S. Camera is supported by Miur through Rita Levi Montalcini project ‘Prometheus – Probing and Relating Observables with Multi-wavelength Experiments To Help Enlightening the Universe’s Structure’. A. Pourtsidou is a UK Research and Innovation Future Leaders Fellow, grant MR/S016066/1. The Euclid Consortium acknowledges the European Space Agency and a number of agencies and institutes that have supported the development of Euclid, in particular the Academy of Finland, the Agenzia Spaziale Italiana, the Belgian Science Policy, the Canadian Euclid Consortium, the Centre National d’Etudes Spatiales, the Deutsches Zentrum für Luftund Raumfahrt, the Danish Space Research Institute, the Fundação para a Ciência e a Tecnologia, the Ministerio de Econo-mia y Competitividad, the National Aeronautics and Space Administration, the Netherlandse Onderzoekschool Voor Astronomie, the Norwegian Space Agency, the Romanian Space Agency, the State Secretariat for Education, Research and Innovation (SERI) at the Swiss Space Office (SSO), and the United Kingdom Space Agency. A complete and detailed list is available on the Euclid web site (http://www.euclid-ec.org).
Publisher Copyright:
© ESO 2021.
PY - 2021/11/11
Y1 - 2021/11/11
N2 - Photometric redshifts (photo-zs) are one of the main ingredients in the analysis of cosmological probes. Their accuracy particularly affects the results of the analyses of galaxy clustering with photometrically selected galaxies (GCph) and weak lensing. In the next decade, space missions such as Euclid will collect precise and accurate photometric measurements for millions of galaxies. These data should be complemented with upcoming ground-based observations to derive precise and accurate photo-zs. In this article we explore how the tomographic redshift binning and depth of ground-based observations will affect the cosmological constraints expected from the Euclid mission. We focus on GCph and extend the study to include galaxy-galaxy lensing (GGL). We add a layer of complexity to the analysis by simulating several realistic photo-z distributions based on the Euclid Consortium Flagship simulation and using a machine learning photo-z algorithm. We then use the Fisher matrix formalism together with these galaxy samples to study the cosmological constraining power as a function of redshift binning, survey depth, and photo-z accuracy. We find that bins with an equal width in redshift provide a higher figure of merit (FoM) than equipopulated bins and that increasing the number of redshift bins from ten to 13 improves the FoM by 35% and 15% for GCph and its combination with GGL, respectively. For GCph, an increase in the survey depth provides a higher FoM. However, when we include faint galaxies beyond the limit of the spectroscopic training data, the resulting FoM decreases because of the spurious photo-zs. When combining GCph and GGL, the number density of the sample, which is set by the survey depth, is the main factor driving the variations in the FoM. Adding galaxies at faint magnitudes and high redshift increases the FoM, even when they are beyond the spectroscopic limit, since the number density increase compensates for the photo-z degradation in this case. We conclude that there is more information that can be extracted beyond the nominal ten tomographic redshift bins of Euclid and that we should be cautious when adding faint galaxies into our sample since they can degrade the cosmological constraints.
AB - Photometric redshifts (photo-zs) are one of the main ingredients in the analysis of cosmological probes. Their accuracy particularly affects the results of the analyses of galaxy clustering with photometrically selected galaxies (GCph) and weak lensing. In the next decade, space missions such as Euclid will collect precise and accurate photometric measurements for millions of galaxies. These data should be complemented with upcoming ground-based observations to derive precise and accurate photo-zs. In this article we explore how the tomographic redshift binning and depth of ground-based observations will affect the cosmological constraints expected from the Euclid mission. We focus on GCph and extend the study to include galaxy-galaxy lensing (GGL). We add a layer of complexity to the analysis by simulating several realistic photo-z distributions based on the Euclid Consortium Flagship simulation and using a machine learning photo-z algorithm. We then use the Fisher matrix formalism together with these galaxy samples to study the cosmological constraining power as a function of redshift binning, survey depth, and photo-z accuracy. We find that bins with an equal width in redshift provide a higher figure of merit (FoM) than equipopulated bins and that increasing the number of redshift bins from ten to 13 improves the FoM by 35% and 15% for GCph and its combination with GGL, respectively. For GCph, an increase in the survey depth provides a higher FoM. However, when we include faint galaxies beyond the limit of the spectroscopic training data, the resulting FoM decreases because of the spurious photo-zs. When combining GCph and GGL, the number density of the sample, which is set by the survey depth, is the main factor driving the variations in the FoM. Adding galaxies at faint magnitudes and high redshift increases the FoM, even when they are beyond the spectroscopic limit, since the number density increase compensates for the photo-z degradation in this case. We conclude that there is more information that can be extracted beyond the nominal ten tomographic redshift bins of Euclid and that we should be cautious when adding faint galaxies into our sample since they can degrade the cosmological constraints.
KW - Cosmological parameters
KW - Galaxies: distances and redshifts
KW - Surveys
KW - Techniques: photometric
UR - http://www.scopus.com/inward/record.url?scp=85119220101&partnerID=8YFLogxK
U2 - 10.1051/0004-6361/202141061
DO - 10.1051/0004-6361/202141061
M3 - Article
AN - SCOPUS:85119220101
SN - 0004-6361
VL - 655
JO - Astronomy and Astrophysics
JF - Astronomy and Astrophysics
M1 - A44
ER -