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Euclid preparation: XXXVI. Modelling the weak lensing angular power spectrum

Title:	Euclid preparation: XXXVI. Modelling the weak lensing angular power spectrum
Authors:	Deshpande, AC; Kitching, T; Hall, A; Brown, ML; Aghanim, N; Amendola, L; Andreon, S; Auricchio, N; Baldi, M; Bardelli, S; Bender, R; Bonino, D; Branchini, E; Brescia, M; Brinchmann, J; Camera, S; Candini, GP; Capobianco, V; Carbone, C; Cardone, VF; Carretero, J; Casas, S; Castander, FJ; Castellano, M; Cavuoti, S; Cimatti, A; Cledassou, R; Congedo, G; Conselice, CJ; Conversi, L; Corcione, L; Courbin, F; Courtois, HM; Cropper, M; Da Silva, A; Degaudenzi, H; Douspis, M; Dubath, F; Duncan, CAJ; Dupac, X; Farina, M; Farrens, S; Ferriol, S; Fosalba, P; Frailis, M; Franceschi, E; Fumana, M; Galeotta, S; Garilli, B; Gillis, B; Giocoli, C; Grazian, A; Grupp, F; Haugan, SVH; Hoekstra, H; Holmes, W; Hornstrup, A; Hudelot, P; Jahnke, K; Keihänen, E; Kermiche, S; Kilbinger, M; Kunz, M; Kurki-Suonio, H; Ligori, S; Lilje, PB; Lindholm, V; Lloro, I; Maiorano, E; Mansutti, O; Marggraf, O; Markovic, K; Martinet, N; Marulli, F; Massey, R; Mei, S; Mellier, Y; Meneghetti, M; Meylan, G; Moscardini, L; Niemi, S-M; Nightingale, JW; Nutma, T; Padilla, C; Paltani, S; Pasian, F; Pedersen, K; Pettorino, V; Pires, S; Polenta, G; Pollack, J; Poncet, M; Popa, LA; Raison, F; Renzi, A; Rhodes, J; Riccio, G; Romelli, E; Roncarelli, M; Rossetti, E; Saglia, R; Sapone, D; Sartoris, B; Schneider, P; Schrabback, T; Secroun, A; Seidel, G; Serrano, S; Sirignano, C; Sirri, G; Stanco, L; Tallada-Crespí, P; Taylor, AN; Tereno, I; Toledo-Moreo, R; Torradeflot, F; Tutusaus, I; Valentijn, EA; Valenziano, L; Vassallo, T; Wang, Y; Weller, J; Zacchei, A; Zamorani, G; Zoubian, J; Zucca, E; Boucaud, A; Bozzo, E; Colodro-Conde, C; Di Ferdinando, D; Fabbian, G; Graciá-Carpio, J; Mauri, N; Scottez, V; Tenti, M; Akrami, Y; Baccigalupi, C; Balaguera-Antolínez, A; Ballardini, M; Bernardeau, F; Biviano, A; Blanchard, A; Borlaff, AS; Burigana, C; Cabanac, R; Cappi, A; Carvalho, CS; Castignani, G; Castro, T; Chambers, KC; Cooray, AR; Coupon, J; Davini, S; de la Torre, S; De Lucia, G; Desprez, G; Dole, H; Escartin, JA; Escoffier, S; Ferrero, I; Finelli, F; Garcia-Bellido, J; George, K; Giacomini, F; Gozaliasl, G; Hildebrandt, H; Kajava, JJE; Kansal, V; Kirkpatrick, CC; Legrand, L; Loureiro, A; Macias-Perez, J; Magliocchetti, M; Mainetti, G; Maoli, R; Martinelli, M; Martins, CJAP; Matthew, S; Maurin, L; Metcalf, RB; Monaco, P; Morgante, G; Nadathur, S; Nucita, AA; Patrizii, L; Peel, A; Pöntinen, M; Popa, V; Porciani, C; Potter, D; Pourtsidou, A; Reimberg, P; Sakr, Z; Sánchez, AG; Schneider, A; Sefusatti, E; Sereno, M; Shulevski, A; Spurio Mancini, A; Steinwagner, J; Teyssier, R; Viel, M; Zinchenko, IA; Fleury, P
Source:	Astronomy & Astrophysics , 684 , Article A138. (2024)
Publisher Information:	EDP Sciences
Publication Year:	2024
Collection:	University College London: UCL Discovery
Subject Terms:	gravitation; gravitational lensing: weak; cosmological parameters; dark energy
Description:	This work considers which higher order modeling effects on the cosmic shear angular power spectra must be taken into account for Euclid. We identified the relevant terms and quantified their individual and cumulative impact on the cosmological parameter inferences from Euclid. We computed the values of these higher order effects using analytic expressions and calculated the impact on cosmological parameter estimations using the Fisher matrix formalism. We reviewed 24 effects and determined the ones that potentially need to be accounted for, namely: the reduced shear approximation, magnification bias, source-lens clustering, source obscuration, local Universe effects, and the flat Universe assumption. After computing these effects explicitly and calculating their cosmological parameter biases, using a maximum multipole of ℓ = 5000, we find that the magnification bias, source-lens clustering, source obscuration, and local Universe terms individually produce significant (> 0.25σ) cosmological biases in one or more parameters; accordingly, these effects must be accounted for and warrant further investigation. In total, we find biases in Ωm, Ωb, h, and σ8 of 0.73σ, 0.28σ, 0.25σ, and −0.79σ, respectively, for the flat ΛCDM. For the w0waCDM case, we found biases in Ωm, Ωb, h, ns, σ8, and wa of 1.49σ, 0.35σ, −1.36σ, 1.31σ, −0.84σ, and −0.35σ, respectively. These are increased relative to the ΛCDM due to additional degeneracies as a function of redshift and scale.
Document Type:	article in journal/newspaper
File Description:	text
Language:	English
Relation:	https://discovery.ucl.ac.uk/id/eprint/10192888/
Availability:	https://discovery.ucl.ac.uk/id/eprint/10192888/1/Spurio%20Mancini_aa46110-23.pdf; https://discovery.ucl.ac.uk/id/eprint/10192888/
Rights:	open
Accession Number:	edsbas.FA899D76
Database:	BASE