Euclid: Calibrating photometric redshifts with spectroscopic   cross-correlations

K. Naidoo; H. Johnston; B. Joachimi; J. L. van den Busch; H.; Hildebrandt; O. Ilbert; O. Lahav; N. Aghanim; B. Altieri; A. Amara; M. Baldi,; R. Bender; C. Bodendorf; E. Branchini; M. Brescia; J. Brinchmann; S. Camera,; V. Capobianco; C. Carbone; J. Carretero; F. J. Castander; M. Castellano; S.; Cavuoti; A. Cimatti; R. Cledassou; G. Congedo; C. J. Conselice; L. Conversi,; Y. Copin; L. Corcione; F. Courbin; M. Cropper; A. Da Silva; H. Degaudenzi; J.; Dinis; F. Dubath; X. Dupac; S. Dusini; S. Farrens; S. Ferriol; P. Fosalba; M.; Frailis; E. Franceschi; P. Franzetti; M. Fumana; S. Galeotta; B. Garilli; W.; Gillard; B. Gillis; C. Giocoli; A. Grazian; F. Grupp; S. V. H. Haugan; W.; Holmes; F. Hormuth; A. Hornstrup; K. Jahnke; M. K\"ummel; A. Kiessling; M.; Kilbinger; T. Kitching; R. Kohley; H. Kurki-Suonio; S. Ligori; P. B. Lilje,; I. Lloro; E. Maiorano; O. Mansutti; O. Marggraf; K. Markovic; F. Marulli; R.; Massey; S. Maurogordato; M. Meneghetti; E. Merlin; G. Meylan; M. Moresco; L.; Moscardini; E. Munari; R. Nakajima; S. M. Niemi; C. Padilla; S. Paltani; F.; Pasian; K. Pedersen; W. J. Percival; V. Pettorino; S. Pires; G. Polenta; M.; Poncet; L. Popa; L. Pozzetti; F. Raison; R. Rebolo; A. Renzi; J. Rhodes; G.; Riccio; E. Romelli; C. Rosset; E. Rossetti; R. Saglia; D. Sapone; B.; Sartoris; P. Schneider; A. Secroun; G. Seidel; C. Sirignano; G. Sirri; J.-L.; Starck; C. Surace; P. Tallada-Cresp\'i; A. N. Taylor; I. Tereno; R.; Toledo-Moreo; F. Torradeflot; I. Tutusaus; E. A. Valentijn; L. Valenziano; T.; Vassallo; Y. Wang; J. Weller; M. Wetzstein; A. Zacchei; G. Zamorani; J.; Zoubian; S. Andreon; D. Maino; V. Scottez; A. H. Wright

arXiv:2208.10503·astro-ph.CO·February 27, 2023

Euclid: Calibrating photometric redshifts with spectroscopic cross-correlations

K. Naidoo, H. Johnston, B. Joachimi, J. L. van den Busch, H., Hildebrandt, O. Ilbert, O. Lahav, N. Aghanim, B. Altieri, A. Amara, M. Baldi,, R. Bender, C. Bodendorf, E. Branchini, M. Brescia, J. Brinchmann, S. Camera,, V. Capobianco, C. Carbone, J. Carretero, F. J. Castander

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TL;DR

This paper demonstrates that clustering redshifts can calibrate Euclid's redshift distributions with high precision, surpassing requirements, by using mock data and models, and discusses systematic biases and future extensions.

Contribution

It introduces a method to calibrate Euclid's redshift distributions using clustering redshifts with mock simulations, achieving accuracy beyond current requirements.

Findings

01

Clustering redshifts measure mean redshift to better than 0.01 accuracy.

02

Method exceeds Euclid's calibration requirement by a factor of three.

03

Systematic biases are identified as a key challenge for future work.

Abstract

Cosmological constraints from key probes of the Euclid imaging survey rely critically on the accurate determination of the true redshift distributions, $n (z)$ , of tomographic redshift bins. We determine whether the mean redshift, $< z >$ , of ten Euclid tomographic redshift bins can be calibrated to the Euclid target uncertainties of $σ (< z >) < 0.002 (1 + z)$ via cross-correlation, with spectroscopic samples akin to those from the Baryon Oscillation Spectroscopic Survey (BOSS), Dark Energy Spectroscopic Instrument (DESI), and Euclid's NISP spectroscopic survey. We construct mock Euclid and spectroscopic galaxy samples from the Flagship simulation and measure small-scale clustering redshifts up to redshift $z < 1.8$ with an algorithm that performs well on current galaxy survey data. The clustering measurements are then fitted to two $n (z)$ models: one is the true $n (z)$ with a free mean; the…

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