Beecroft Institute for Particle Astrophysics and Cosmology

Joint tomographic measurement of thermal Sunyaev Zeldovich and the cosmic infrared background

(2026)

Authors:

Adrien La Posta, David Alonso, Carlos García-García, Sara Maleubre

Euclid preparation

Astronomy & Astrophysics EDP Sciences 707 (2026) a234

Authors:

WL Matthewson, R Durrer, S Camera, I Tutusaus, B Altieri, A Amara, S Andreon, N Auricchio, C Baccigalupi, M Baldi, S Bardelli, P Battaglia, A Biviano, E Branchini, M Brescia, G Cañas-Herrera, V Capobianco, C Carbone, VF Cardone, J Carretero, S Casas, M Castellano, G Castignani, S Cavuoti, KC Chambers, A Cimatti, C Colodro-Conde, G Congedo, CJ Conselice, L Conversi, Y Copin, F Courbin, HM Courtois, A Da Silva, H Degaudenzi, G De Lucia, H Dole, F Dubath, CAJ Duncan, X Dupac, S Dusini, S Escoffier, M Farina, F Faustini, S Ferriol, F Finelli, M Frailis, E Franceschi, M Fumana, S Galeotta, K George, B Gillis, C Giocoli, J Gracia-Carpio, A Grazian, F Grupp, SVH Haugan, W Holmes, F Hormuth, A Hornstrup, K Jahnke, M Jhabvala, B Joachimi, E Keihänen, S Kermiche, A Kiessling, B Kubik, M Kunz, H Kurki-Suonio, AMC Le Brun, S Ligori, PB Lilje, V Lindholm, I Lloro, G Mainetti, D Maino, E Maiorano, O Mansutti, S Marcin, O Marggraf, M Martinelli, N Martinet, F Marulli, RJ Massey, E Medinaceli, S Mei, Y Mellier, M Meneghetti, E Merlin, G Meylan, A Mora, M Moresco, B Morin, L Moscardini, C Neissner, S-M Niemi, C Padilla, S Paltani, F Pasian, K Pedersen, WJ Percival, V Pettorino, S Pires, G Polenta, M Poncet, LA Popa, F Raison, R Rebolo, A Renzi, J Rhodes, G Riccio, E Romelli, M Roncarelli, R Saglia, Z Sakr, AG Sánchez, D Sapone, B Sartoris, P Schneider, T Schrabback, A Secroun, E Sefusatti, G Seidel, S Serrano, P Simon, C Sirignano, G Sirri, A Spurio Mancini, L Stanco, J-L Starck, J Steinwagner, P Tallada-Crespí, AN Taylor, I Tereno, N Tessore, S Toft, R Toledo-Moreo, F Torradeflot, L Valenziano, J Valiviita, T Vassallo, A Veropalumbo, Y Wang, J Weller, G Zamorani, E Zucca, M Ballardini, E Bozzo, C Burigana, R Cabanac, M Calabrese, A Cappi, D Di Ferdinando, JA Escartin Vigo, L Gabarra, WG Hartley, J Martín-Fleitas, S Matthew, M Maturi, N Mauri, RB Metcalf, A Pezzotta, M Pöntinen, C Porciani, I Risso, V Scottez, M Sereno, M Tenti, M Viel, M Wiesmann, Y Akrami, S Alvi, IT Andika, S Anselmi, M Archidiacono, F Atrio-Barandela, D Bertacca, M Bethermin, L Blot, M Bonici, S Borgani, ML Brown, S Bruton, A Calabro, B Camacho Quevedo, F Caro, CS Carvalho, T Castro, F Cogato, S Conseil, AR Cooray, S Davini, G Desprez, A Díaz-Sánchez, JJ Diaz, S Di Domizio, JM Diego, MY Elkhashab, A Enia, Y Fang, AG Ferrari, A Finoguenov, A Franco, K Ganga, J García-Bellido, T Gasparetto, V Gautard, E Gaztanaga, F Giacomini, F Gianotti, G Gozaliasl, CM Gutierrez, S Hemmati, C Hernández-Monteagudo, H Hildebrandt, J Hjorth, JJE Kajava, Y Kang, V Kansal, D Karagiannis, K Kiiveri, J Kim, CC Kirkpatrick, S Kruk, F Lacasa, M Lattanzi, J Le Graet, L Legrand, M Lembo, F Lepori, G Leroy, GF Lesci, J Lesgourgues, TI Liaudat, J Macias-Perez, G Maggio, M Magliocchetti, R Maoli, CJAP Martins, L Maurin, M Miluzio, P Monaco, C Moretti, G Morgante, S Nadathur, K Naidoo, A Navarro-Alsina, S Nesseris, D Paoletti, F Passalacqua, K Paterson, L Patrizii, A Pisani, D Potter, S Quai, M Radovich, G Rodighiero, S Sacquegna, M Sahlén, DB Sanders, E Sarpa, A Schneider, D Sciotti, E Sellentin, A Silvestri, LC Smith, K Tanidis, C Tao, G Testera, R Teyssier, S Tosi, A Troja, M Tucci, C Valieri, A Venhola, D Vergani, F Vernizzi, G Verza, NA Walton

Abstract:

We compared the performance of the flat-sky approximation and Limber approximation for the clustering analysis of the photometric galaxy catalogue of Euclid . We studied a 6-bin configuration, representing the first data release (DR1), and a 13-bin configuration, representing the third and final data release (DR3). We find that the Limber approximation is sufficiently accurate for the analysis of the wide bins of DR1. Instead, the 13 bins of DR3 cannot be modelled accurately with the Limber approximation. Instead, the flat-sky approximation is accurate to below 5% in recovering the angular power spectra of galaxy number counts in both cases and can be used to simplify the computation of the full power spectrum in harmonic space for the data analysis of DR3.

Euclid preparation

Astronomy & Astrophysics EDP Sciences 707 (2026) a229

Authors:

M Urbano, P-A Duc, M Poulain, AA Nucita, A Venhola, O Marchal, M Kümmel, H Kong, F Soldano, E Romelli, M Walmsley, T Saifollahi, K Voggel, A Lançon, FR Marleau, E Sola, LK Hunt, J Junais, D Carollo, PM Sanchez-Alarcon, M Baes, F Buitrago, M Cantiello, J-C Cuillandre, H Domínguez Sánchez, A Ferré-Mateu, A Franco, J Gracia-Carpio, R Habas, M Hilker, E Iodice, JH Knapen, MN Le, D Martínez-Delgado, O Müller, F De Paolis, P Papaderos, R Ragusa, J Román, E Saremi, V Testa, B Altieri, L Amendola, S Andreon, N Auricchio, C Baccigalupi, M Baldi, S Bardelli, P Battaglia, A Biviano, E Branchini, M Brescia, S Camera, G Cañas-Herrera, V Capobianco, C Carbone, J Carretero, S Casas, M Castellano, G Castignani, S Cavuoti, A Cimatti, C Colodro-Conde, G Congedo, CJ Conselice, L Conversi, Y Copin, F Courbin, HM Courtois, M Cropper, A Da Silva, H Degaudenzi, G De Lucia, H Dole, F Dubath, CAJ Duncan, X Dupac, S Dusini, S Escoffier, M Farina, R Farinelli, S Ferriol, F Finelli, M Frailis, E Franceschi, M Fumana, S Galeotta, K George, B Gillis, C Giocoli, A Grazian, F Grupp, L Guzzo, SVH Haugan, W Holmes, IM Hook, F Hormuth, A Hornstrup, K Jahnke, M Jhabvala, B Joachimi, E Keihänen, S Kermiche, A Kiessling, B Kubik, M Kunz, H Kurki-Suonio, R Laureijs, AMC Le Brun, S Ligori, PB Lilje, V Lindholm, I Lloro, G Mainetti, D Maino, E Maiorano, O Mansutti, O Marggraf, M Martinelli, N Martinet, F Marulli, RJ Massey, E Medinaceli, S Mei, Y Mellier, M Meneghetti, E Merlin, G Meylan, A Mora, M Moresco, L Moscardini, R Nakajima, C Neissner, S-M Niemi, C Padilla, S Paltani, F Pasian, K Pedersen, V Pettorino, S Pires, G Polenta, M Poncet, LA Popa, L Pozzetti, F Raison, R Rebolo, A Renzi, J Rhodes, G Riccio, M Roncarelli, R Saglia, Z Sakr, D Sapone, B Sartoris, P Schneider, T Schrabback, A Secroun, G Seidel, S Serrano, P Simon, C Sirignano, G Sirri, L Stanco, J-L Starck, J Steinwagner, P Tallada-Crespí, AN Taylor, HI Teplitz, I Tereno, N Tessore, S Toft, R Toledo-Moreo, F Torradeflot, I Tutusaus, L Valenziano, J Valiviita, T Vassallo, G Verdoes Kleijn, A Veropalumbo, Y Wang, J Weller, G Zamorani, IA Zinchenko, E Zucca, M Ballardini, M Bolzonella, E Bozzo, C Burigana, R Cabanac, A Cappi, D Di Ferdinando, JA Escartin Vigo, L Gabarra, M Huertas-Company, J Martín-Fleitas, S Matthew, N Mauri, RB Metcalf, A Pezzotta, M Pöntinen, C Porciani, I Risso, V Scottez, M Sereno, M Tenti, M Viel, M Wiesmann, Y Akrami, IT Andika, S Anselmi, M Archidiacono, F Atrio-Barandela, D Bertacca, M Bethermin, A Blanchard, L Blot, M Bonici, S Borgani, ML Brown, S Bruton, A Calabro, B Camacho Quevedo, F Caro, CS Carvalho, T Castro, F Cogato, S Conseil, AR Cooray, O Cucciati, S Davini, G Desprez, A Díaz-Sánchez, JJ Diaz, S Di Domizio, JM Diego, MY Elkhashab, A Enia, Y Fang, AG Ferrari, A Finoguenov, K Ganga, J García-Bellido, T Gasparetto, V Gautard, E Gaztanaga, F Giacomini, F Gianotti, G Gozaliasl, M Guidi, CM Gutierrez, A Hall, H Hildebrandt, J Hjorth, JJE Kajava, Y Kang, V Kansal, D Karagiannis, K Kiiveri, J Kim, CC Kirkpatrick, S Kruk, J Le Graet, L Legrand, M Lembo, F Lepori, G Leroy, GF Lesci, J Lesgourgues, L Leuzzi, TI Liaudat, A Loureiro, J Macias-Perez, G Maggio, M Magliocchetti, F Mannucci, R Maoli, CJAP Martins, L Maurin, M Miluzio, P Monaco, C Moretti, G Morgante, K Naidoo, A Navarro-Alsina, S Nesseris, D Paoletti, F Passalacqua, K Paterson, L Patrizii, A Pisani, D Potter, S Quai, M Radovich, G Rodighiero, S Sacquegna, M Sahlén, DB Sanders, E Sarpa, A Schneider, D Sciotti, E Sellentin, LC Smith, JG Sorce, K Tanidis, C Tao, G Testera, R Teyssier, S Tosi, A Troja, M Tucci, C Valieri, D Vergani, G Verza, P Vielzeuf, NA Walton

Abstract:

Local Universe dwarf galaxies can serve as both cosmological and mass assembly probes. Deep surveys have enabled the study of these objects down to the low surface brightness (LSB) regime. In this paper, we estimate Euclid ’s dwarf detection capabilities as well as limits of its MERge processing function (MER pipeline), which is responsible for producing the stacked mosaics and final catalogues. To do this, we injected mock dwarf galaxies in a real Euclid Wide Survey (EWS) field in the VIS band and compared the input catalogue to the final MER catalogue. The mock dwarf galaxies were generated using simple Sérsic models with structural parameters (including size and surface brightness) drawn from observed dwarf galaxy catalogues. These simulations represent an idealised case in the sense they do not account for additional factors such as ellipticity, morphology, or crowding. To characterise the detected dwarfs, we used the mean surface brightness inside the effective radius SB e (in mag arcsec −2 ). The final MER catalogues achieve a completenesses of 91% for SB e ∈ [21, 24] and 54% for SB e ∈ [24, 28]. These numbers do not take into account possible contaminants, including confusion with background galaxies at the location of the dwarfs. After taking those effects into account, they respectively became 86% and 38%. The MER pipeline performs a final local background subtraction with a small mesh size, leading to a flux loss for galaxies with R e > 10″. By using the final MER mosaics and reinjecting this local background, we obtained an image in which we recover reliable photometric properties for objects under the arcminute scale. This background-reinjected product is thus suitable for the study of Local Universe dwarf galaxies. Euclid ’s data reduction pipeline serves as a test bed for other deep surveys, particularly regarding background subtraction methods, a key issue in LSB science.

Euclid preparation

Astronomy & Astrophysics EDP Sciences 707 (2026) a233

Authors:

I Risso, A Veropalumbo, E Branchini, E Maragliano, S de la Torre, E Sarpa, P Monaco, BR Granett, S Lee, GE Addison, S Bruton, C Carbone, G Lavaux, K Markovic, K McCarthy, G Parimbelli, F Passalacqua, WJ Percival, C Scarlata, E Sefusatti, Y Wang, M Bonici, F Oppizzi, N Aghanim, B Altieri, A Amara, S Andreon, N Auricchio, C Baccigalupi, M Baldi, A Balestra, S Bardelli, P Battaglia, A Biviano, A Bonchi, D Bonino, M Brescia, J Brinchmann, S Camera, G Cañas-Herrera, V Capobianco, VF Cardone, J Carretero, S Casas, M Castellano, G Castignani, S Cavuoti, KC Chambers, A Cimatti, C Colodro-Conde, G Congedo, CJ Conselice, L Conversi, Y Copin, F Courbin, HM Courtois, M Crocce, A Da Silva, H Degaudenzi, G De Lucia, AM Di Giorgio, H Dole, M Douspis, F Dubath, CAJ Duncan, X Dupac, S Dusini, S Escoffier, M Farina, R Farinelli, F Faustini, S Ferriol, F Finelli, S Fotopoulou, N Fourmanoit, M Frailis, E Franceschi, M Fumana, S Galeotta, K George, W Gillard, B Gillis, C Giocoli, J Gracia-Carpio, A Grazian, F Grupp, L Guzzo, SVH Haugan, W Holmes, F Hormuth, A Hornstrup, P Hudelot, K Jahnke, M Jhabvala, B Joachimi, E Keihänen, S Kermiche, A Kiessling, M Kilbinger, B Kubik, M Kümmel, M Kunz, H Kurki-Suonio, AMC Le Brun, P Liebing, S Ligori, PB Lilje, V Lindholm, I Lloro, G Mainetti, D Maino, E Maiorano, O Mansutti, S Marcin, O Marggraf, M Martinelli, N Martinet, F Marulli, R Massey, S Maurogordato, E Medinaceli, S Mei, M Melchior, Y Mellier, M Meneghetti, E Merlin, G Meylan, A Mora, M Moresco, L Moscardini, R Nakajima, C Neissner, S-M Niemi, JW Nightingale, C Padilla, S Paltani, F Pasian, K Pedersen, V Pettorino, S Pires, G Polenta, M Poncet, LA Popa, L Pozzetti, F Raison, R Rebolo, A Renzi, J Rhodes, G Riccio, E Romelli, M Roncarelli, E Rossetti, R Saglia, Z Sakr, D Sapone, B Sartoris, JA Schewtschenko, P Schneider, T Schrabback, M Scodeggio, A Secroun, G Seidel, M Seiffert, S Serrano, P Simon, C Sirignano, G Sirri, L Stanco, J Steinwagner, C Surace, P Tallada-Crespí, D Tavagnacco, AN Taylor, I Tereno, N Tessore, S Toft, R Toledo-Moreo, F Torradeflot, I Tutusaus, L Valenziano, J Valiviita, T Vassallo, G Verdoes Kleijn, D Vibert, J Weller, G Zamorani, FM Zerbi, E Zucca, V Allevato, M Ballardini, M Bolzonella, E Bozzo, C Burigana, R Cabanac, A Cappi, D Di Ferdinando, JA Escartin Vigo, L Gabarra, WG Hartley, J Martín-Fleitas, S Matthew, N Mauri, RB Metcalf, A Pezzotta, M Pöntinen, C Porciani, V Scottez, M Sereno, M Tenti, M Viel, M Wiesmann, Y Akrami, S Alvi, IT Andika, M Archidiacono, F Atrio-Barandela, S Avila, A Balaguera-Antolinez, C Benoist, D Bertacca, M Bethermin, L Blot, H Böhringer, S Borgani, ML Brown, A Calabro, B Camacho Quevedo, F Caro, CS Carvalho, T Castro, F Cogato, AR Cooray, O Cucciati, S Davini, F De Paolis, G Desprez, A Díaz-Sánchez, JJ Diaz, S Di Domizio, JM Diego, P Dimauro, A Enia, Y Fang, AG Ferrari, A Finoguenov, A Fontana, A Franco, K Ganga, J García-Bellido, T Gasparetto, V Gautard, E Gaztanaga, F Giacomini, F Gianotti, G Gozaliasl, M Guidi, CM Gutierrez, A Hall, S Hemmati, C Hernández-Monteagudo, H Hildebrandt, J Hjorth, S Joudaki, JJE Kajava, Y Kang, V Kansal, D Karagiannis, K Kiiveri, CC Kirkpatrick, S Kruk, V Le Brun, J Le Graet, L Legrand, M Lembo, F Lepori, G Leroy, GF Lesci, L Leuzzi, TI Liaudat, A Loureiro, J Macias-Perez, M Magliocchetti, F Mannucci, R Maoli, CJAP Martins, L Maurin, M Miluzio, C Moretti, G Morgante, S Nadathur, K Naidoo, A Navarro-Alsina, K Paterson, L Patrizii, A Pisani, D Potter, S Quai, M Radovich, P-F Rocci, S Sacquegna, M Sahlén, DB Sanders, A Schneider, D Sciotti, E Sellentin, LC Smith, JG Sorce, K Tanidis, C Tao, G Testera, R Teyssier, S Tosi, A Troja, M Tucci, C Valieri, A Venhola, D Vergani, G Verza, NA Walton

Abstract:

Context. The Euclid galaxy survey is designed to measure the spectroscopic redshift of emission-line galaxies (ELGs) by identifying the H α emission line in their slitless spectra. The efficacy of this approach crucially depends on the signal-to-noise ratio (S/N) of the line, as sometimes noise fluctuations in the spectrum continuum can be misidentified as H α . In addition, other genuine strong emission lines can be mistaken for H α , depending on the redshift of the source. Both effects lead to ambiguities in the redshift measurement that can result in catastrophic redshift errors and the inclusion of ‘interloper’ galaxies in the sample. Aims. This paper forecasts the impact on the galaxy clustering analysis of the expected redshift errors in the Euclid spectroscopic sample. Specifically, it investigates the effect of the redshift interloper contamination on the galaxy two-point correlation function (2PCF) and, in turn, on the inferred growth rate of structure fσ 8 and Alcock–Paczynski (AP) parameters α ∥ and α ⊥ . Methods. This work is based on the analysis of 1000 synthetic spectroscopic catalogues, the EuclidLargeMocks, which mimic the area and selection function of the Euclid Data Release 1 (DR1) sample. We estimated the 2PCF of contaminated catalogues and separated the different contributions, particularly those coming from galaxies with correctly measured redshift and from contaminants. We explored different models of increasing complexity to describe the measured 2PCF at a fixed cosmology, with the aim of identifying the most efficient model to reproduce the data. Finally, we performed a cosmological inference and evaluated the systematic error on the inferred fσ 8 , α ∥ , and α ⊥ values associated with different models. Results. Our results demonstrate that a minimal modelling approach, which only accounts for an attenuation of the clustering signal regardless of the type of contaminants, is sufficient to recover the correct values of fσ 8 , α ∥ , and α ⊥ at DR1. The accuracy and precision of the estimated AP parameters are largely insensitive to the presence of interlopers. The adoption of a minimal modelling induces a 1%–3% systematic error on the growth rate of structure estimation, depending on the considered redshift. However, this error remains smaller than the statistical error expected for the Euclid DR1 analysis.

Euclid preparation

Astronomy & Astrophysics EDP Sciences 707 (2026) a230

Authors:

B Kubik, R Barbier, J Clemens, S Ferriol, A Secroun, G Smadja, W Gillard, N Fourmanoit, A Ealet, S Conseil, J Zoubian, R Kohley, J-C Salvignol, L Conversi, T Maciaszek, H Cho, W Holmes, M Seiffert, A Waczynski, S Wachter, K Jahnke, F Grupp, C Bonoli, L Corcione, S Dusini, E Medinaceli, R Laureijs, GD Racca, A Bonnefoi, M Carle, A Costille, F Ducret, J-L Gimenez, D Le Mignant, L Martin, L Caillat, L Valenziano, N Auricchio, P Battaglia, A Derosa, R Farinelli, F Cogato, G Morgante, M Trifoglio, V Capobianco, S Ligori, E Borsato, C Sirignano, L Stanco, S Ventura, R Toledo-Moreo, L Patrizii, Y Copin, R Foltz, E Prieto, N Aghanim, B Altieri, S Andreon, C Baccigalupi, M Baldi, A Balestra, S Bardelli, F Bernardeau, A Biviano, A Bonchi, E Branchini, M Brescia, J Brinchmann, S Camera, G Cañas-Herrera, C Carbone, J Carretero, S Casas, FJ Castander, M Castellano, G Castignani, S Cavuoti, KC Chambers, A Cimatti, C Colodro-Conde, G Congedo, CJ Conselice, F Courbin, HM Courtois, A Da Silva, R da Silva, H Degaudenzi, G De Lucia, AM Di Giorgio, H Dole, M Douspis, F Dubath, CAJ Duncan, X Dupac, S Escoffier, M Farina, F Faustini, F Finelli, S Fotopoulou, M Frailis, E Franceschi, M Fumana, S Galeotta, B Gillis, C Giocoli, J Gracia-Carpio, BR Granett, A Grazian, L Guzzo, SVH Haugan, J Hoar, H Hoekstra, IM Hook, F Hormuth, A Hornstrup, P Hudelot, M Jhabvala, E Keihänen, S Kermiche, A Kiessling, M Kümmel, M Kunz, H Kurki-Suonio, Q Le Boulc’h, AMC Le Brun, P Liebing, PB Lilje, V Lindholm, I Lloro, G Mainetti, D Maino, E Maiorano, O Mansutti, S Marcin, O Marggraf, M Martinelli, N Martinet, F Marulli, R Massey, S Maurogordato, HJ McCracken, S Mei, M Melchior, Y Mellier, M Meneghetti, E Merlin, G Meylan, A Mora, M Moresco, PW Morris, L Moscardini, R Nakajima, C Neissner, RC Nichol, S-M Niemi, C Padilla, S Paltani, F Pasian, K Pedersen, WJ Percival, V Pettorino, S Pires, G Polenta, M Poncet, LA Popa, L Pozzetti, F Raison, R Rebolo, A Renzi, J Rhodes, G Riccio, E Romelli, M Roncarelli, E Rossetti, R Saglia, Z Sakr, D Sapone, B Sartoris, JA Schewtschenko, M Schirmer, P Schneider, T Schrabback, M Scodeggio, E Sefusatti, G Seidel, S Serrano, P Simon, G Sirri, J Steinwagner, P Tallada-Crespí, D Tavagnacco, AN Taylor, HI Teplitz, I Tereno, S Toft, F Torradeflot, A Tsyganov, I Tutusaus, J Valiviita, T Vassallo, G Verdoes Kleijn, A Veropalumbo, Y Wang, J Weller, A Zacchei, G Zamorani, FM Zerbi, E Zucca, V Allevato, M Ballardini, M Bolzonella, E Bozzo, C Burigana, R Cabanac, A Cappi, P Casenove, D Di Ferdinando, JA Escartin Vigo, L Gabarra, WG Hartley, J Martín-Fleitas, S Matthew, N Mauri, RB Metcalf, A Pezzotta, M Pöntinen, C Porciani, I Risso, V Scottez, M Sereno, M Tenti, M Viel, M Wiesmann, Y Akrami, IT Andika, S Anselmi, M Archidiacono, F Atrio-Barandela, D Bertacca, M Bethermin, A Blanchard, L Blot, S Borgani, ML Brown, S Bruton, A Calabro, B Camacho Quevedo, F Caro, CS Carvalho, T Castro, Y Charles, R Chary, AR Cooray, O Cucciati, S Davini, F De Paolis, G Desprez, A Díaz-Sánchez, S Di Domizio, JM Diego, P Dimauro, A Enia, Y Fang, AMN Ferguson, AG Ferrari, A Finoguenov, A Fontana, A Franco, K Ganga, J García-Bellido, T Gasparetto, V Gautard, E Gaztanaga, F Giacomini, F Gianotti, G Gozaliasl, M Guidi, CM Gutierrez, A Hall, H Hildebrandt, J Hjorth, JJE Kajava, Y Kang, V Kansal, D Karagiannis, K Kiiveri, CC Kirkpatrick, S Kruk, J Le Graet, L Legrand, M Lembo, F Lepori, G Leroy, GF Lesci, J Lesgourgues, L Leuzzi, TI Liaudat, A Loureiro, J Macias-Perez, G Maggio, M Magliocchetti, C Mancini, F Mannucci, R Maoli, CJAP Martins, L Maurin, M Miluzio, P Monaco, A Montoro, C Moretti, C Murray, S Nadathur, K Naidoo, A Navarro-Alsina, F Passalacqua, K Paterson, A Pisani, D Potter, S Quai, M Radovich, P-F Rocci, S Sacquegna, M Sahlén, DB Sanders, E Sarpa, A Schneider, D Sciotti, E Sellentin, G Setnikar, LC Smith, K Tanidis, C Tao, G Testera, R Teyssier, S Tosi, A Troja, M Tucci, C Valieri, A Venhola, D Vergani, G Verza, JR Weaver, L Zalesky

Abstract:

This paper describes the objectives, design, and findings of the pre-launch ground characterisation campaigns of the Euclid infrared detectors. The aim of the ground characterisations is to evaluate the performance of the detectors, to calibrate the pixel response, and to derive the pixel response correction methods. The detectors have been tested and characterised in the facilities set up for this purpose. The pixel properties, including baseline, bad pixels, quantum efficiency, inter pixel capacitance, quantum efficiency, dark current, readout noise, conversion gain, response non-linearity, and image persistence were measured and characterised for each pixel. We describe in detail the test flow definition that allows us to derive the pixel properties and we present the data acquisition and data quality check software implemented for this purpose. We also outline the measurement protocols of all the pixel properties presented and we provide a comprehensive overview of the performance of the Euclid infrared detectors as derived after tuning the operating parameters of the detectors. The main conclusion of this work is that the performance of the infrared detectors Euclid meets the requirements. Pixels classified as non-functioning accounted for less than 0.2% of all science pixels. The interpixel capacitance (IPC) coupling is minimal, the cross-talk between adjacent pixels is less than 1% between adjacent pixels, and 95% of the pixels show a quantum efficienty (QE) greater than 80% across the entire spectral range of the Euclid mission. The conversion gain is approximately 0.52 ADU/e − , with a variation of less than 1% between channels of the same detector. The reset noise is approximately equal to 23 ADU rms after reference pixel correction. The readout noise of a single frame is approximately 13 e − rms while the signal estimator noise is measured at 7 e − rms in photometric mode and 9 e − rms in spectroscopic acquisition mode. The deviation from linear response at signal levels up to 80 ke − is less than 5% for 95% of the pixels. Median persistence amplitudes are less than 0.3% of the signal, though persistence exhibits significant spatial variation and differences between detectors.