Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes

EUCLID Consortium; N. Frusciante; F. Pace; V. F. Cardone; S. Casas; I. Tutusaus; M. Ballardini; E. Bellini; G. Benevento; B. Bose; P. Valageas; N. Bartolo; P. Brax; P. G. Ferreira; F. Finelli; K. Koyama; L. Legrand; L. Lombriser; D. Paoletti; M. Pietroni; A. Rozas-Fernández; Z. Sakr; A. Silvestri; F. Vernizzi; H. A. Winther; N. Aghanim; L. Amendola; N. Auricchio; R. Azzollini; M. Baldi; D. Bonino; E. Branchini; M. Brescia; J. Brinchmann; S. Camera; V. Capobianco; C. Carbone; J. Carretero; M. Castellano; S. Cavuoti; A. Cimatti; R. Cledassou; G. Congedo; 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; S. Galeotta; B. Gillis; C. Giocoli; A. Grazian; F. Grupp; L. Guzzo; S. V. H. Haugan; W. Holmes; F. Hormuth; A. Hornstrup; K. Jahnke; S. Kermiche; A. Kiessling; M. Kilbinger; T. Kitching; M. Kunz; H. Kurki-Suonio; S. Ligori; P. B. Lilje; I. Lloro; E. Maiorano; O. Mansutti; O. Marggraf; K. Markovic; F. Marulli; R. Massey; E. Medinaceli; M. Meneghetti; G. Meylan; M. Moresco; L. Moscardini; E. Munari; S. M. Niemi; J. Nightingale; C. Padilla; S. Paltani; F. Pasian; K. Pedersen; W. J. Percival; V. Pettorino; G. Polenta; M. Poncet; L. Popa; F. Raison; R. Rebolo; A. Renzi; J. Rhodes; G. Riccio; E. Romelli; R. Saglia; D. Sapone; B. Sartoris; A. Secroun; G. Seidel; C. Sirignano; G. Sirri; L. Stanco; C. Surace; P. Tallada-Crespí; A. N. Taylor; I. Tereno; R. Toledo-Moreo; F. Torradeflot; E. A. Valentijn; L. Valenziano; T. Vassallo; G. A. Verdoes Kleijn; Y. Wang; A. Zacchei; G. Zamorani; J. Zoubian; V. Scottez

doi:10.1051/0004-6361/202347526

Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes

EUCLID Consortium, N. Frusciante^*, F. Pace, V. F. Cardone, S. Casas, I. Tutusaus, M. Ballardini, E. Bellini, G. Benevento, B. Bose, P. Valageas, N. Bartolo, P. Brax, P. G. Ferreira, F. Finelli, K. Koyama, L. Legrand, L. Lombriser, D. Paoletti, M. PietroniA. Rozas-Fernández, Z. Sakr, A. Silvestri, F. Vernizzi, H. A. Winther, N. Aghanim, L. Amendola, N. Auricchio, R. Azzollini, M. Baldi, D. Bonino, E. Branchini, M. Brescia, J. Brinchmann, S. Camera, V. Capobianco, C. Carbone, J. Carretero, M. Castellano, S. Cavuoti, A. Cimatti, R. Cledassou, G. Congedo, 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, S. Galeotta, B. Gillis, C. Giocoli, A. Grazian, F. Grupp, L. Guzzo, S. V. H. Haugan, W. Holmes, F. Hormuth, A. Hornstrup, K. Jahnke, S. Kermiche, A. Kiessling, M. Kilbinger, T. Kitching, M. Kunz, H. Kurki-Suonio, S. Ligori, P. B. Lilje, I. Lloro, E. Maiorano, O. Mansutti, O. Marggraf, K. Markovic, F. Marulli, R. Massey, E. Medinaceli, M. Meneghetti, G. Meylan, M. Moresco, L. Moscardini, E. Munari, S. M. Niemi, J. Nightingale, C. Padilla, S. Paltani, F. Pasian, K. Pedersen, W. J. Percival, V. Pettorino, G. Polenta, M. Poncet, L. Popa, F. Raison, R. Rebolo, A. Renzi, J. Rhodes, G. Riccio, E. Romelli, R. Saglia, D. Sapone, B. Sartoris, A. Secroun, G. Seidel, C. Sirignano, G. Sirri, L. Stanco, C. Surace, P. Tallada-Crespí, A. N. Taylor, I. Tereno, R. Toledo-Moreo, F. Torradeflot, E. A. Valentijn, L. Valenziano, T. Vassallo, G. A. Verdoes Kleijn, Y. Wang, A. Zacchei, G. Zamorani, J. Zoubian, V. Scottez

^*Corresponding author for this work

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

Context. The future Euclid space satellite mission will offer an invaluable opportunity to constrain modifications to Einstein’s general relativity at cosmic scales. In this paper, we focus on modified gravity models characterised, at linear scales, by a scale-independent growth of perturbations while featuring different testable types of derivative screening mechanisms at smaller non-linear scales.

Aims. We considered three specific models, namely Jordan-Brans-Dicke, a scalar-tensor theory with a flat potential, the normal branch of Dvali-Gabadadze-Porrati (nDGP) gravity, a braneworld model in which our Universe is a four-dimensional brane embedded in a five-dimensional Minkowski space-time, and k-mouflage gravity, an extension of k-essence scenarios with a universal coupling of the scalar field to matter. In preparation for real data, we provide forecasts from spectroscopic and photometric primary probes by Euclid on the cosmological parameters and the additional parameters of the models, respectively, ωBD, Ωгc and ϵ2,0, which quantify the deviations from general relativity. This analysis will improve our knowledge of the cosmology of these modified gravity models.

Methods. The forecast analysis employs the Fisher matrix method applied to weak lensing (WL); photometric galaxy clustering (GCph), spectroscopic galaxy clustering (GCsp) and the cross-correlation (XC) between GCph and WL. For the Euclid survey specifications, we define three scenarios that are characterised by different cuts in the maximum multipole and wave number, to assess the constraining power of non-linear scales. For each model we considered two fiducial values for the corresponding model parameter.

Results. In an optimistic setting at 68.3% confidence interval, we find the following percentage relative errors with Euclid alone: for log10 ωBD, with a fiducial value of ωBD = 800, 27.1% using GCsp alone, 3.6% using GCph+WL+XC and 3.2% using GCph+WL+XC+GCsp; for log10 Ωгc, with a fiducial value of Ωгc = 0.25, we find 93.4, 20 and 15% respectively; and finally, for ϵ2,0 = −0.04, we find 3.4%, 0.15%, and 0.14%. From the relative errors for fiducial values closer to their ΛCDM limits, we find that most of the constraining power is lost. Our results highlight the importance of the constraining power from non-linear scales.

Original language	English
Article number	A133
Pages (from-to)	1-22
Number of pages	22
Journal	Astronomy and Astrophysics
Volume	690
DOIs	https://doi.org/10.1051/0004-6361/202347526
Publication status	Published - 4 Oct 2024

Keywords / Materials (for Non-textual outputs)

cosmology: theory
large-scale structure of Universe

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10.1051/0004-6361/202347526Licence: Creative Commons: Attribution (CC-BY)

https://arxiv.org/abs/2306.12368Licence: Creative Commons: Attribution (CC-BY)

Novel Non-linear Techniques for Cosmic Large Scale Structure
Bose, B. (Principal Investigator)
Engineering and Physical Sciences Research Council
1/04/22 → 31/01/26
Project: Research

Cite this

EUCLID Consortium, Frusciante, N., Pace, F., Cardone, V. F., Casas, S., Tutusaus, I., Ballardini, M., Bellini, E., Benevento, G., Bose, B., Valageas, P., Bartolo, N., Brax, P., Ferreira, P. G., Finelli, F., Koyama, K., Legrand, L., Lombriser, L., Paoletti, D., ... Scottez, V. (2024). Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes. Astronomy and Astrophysics, 690, 1-22. Article A133. https://doi.org/10.1051/0004-6361/202347526

@article{c4ab4cc641b94dffa1235429d660b7d1,

title = "Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes",

abstract = "Context. The future Euclid space satellite mission will offer an invaluable opportunity to constrain modifications to Einstein{\textquoteright}s general relativity at cosmic scales. In this paper, we focus on modified gravity models characterised, at linear scales, by a scale-independent growth of perturbations while featuring different testable types of derivative screening mechanisms at smaller non-linear scales. Aims. We considered three specific models, namely Jordan-Brans-Dicke, a scalar-tensor theory with a flat potential, the normal branch of Dvali-Gabadadze-Porrati (nDGP) gravity, a braneworld model in which our Universe is a four-dimensional brane embedded in a five-dimensional Minkowski space-time, and k-mouflage gravity, an extension of k-essence scenarios with a universal coupling of the scalar field to matter. In preparation for real data, we provide forecasts from spectroscopic and photometric primary probes by Euclid on the cosmological parameters and the additional parameters of the models, respectively, ωBD, Ωгc and ϵ2,0, which quantify the deviations from general relativity. This analysis will improve our knowledge of the cosmology of these modified gravity models. Methods. The forecast analysis employs the Fisher matrix method applied to weak lensing (WL); photometric galaxy clustering (GCph), spectroscopic galaxy clustering (GCsp) and the cross-correlation (XC) between GCph and WL. For the Euclid survey specifications, we define three scenarios that are characterised by different cuts in the maximum multipole and wave number, to assess the constraining power of non-linear scales. For each model we considered two fiducial values for the corresponding model parameter. Results. In an optimistic setting at 68.3\% confidence interval, we find the following percentage relative errors with Euclid alone: for log10 ωBD, with a fiducial value of ωBD = 800, 27.1\% using GCsp alone, 3.6\% using GCph+WL+XC and 3.2\% using GCph+WL+XC+GCsp; for log10 Ωгc, with a fiducial value of Ωгc = 0.25, we find 93.4, 20 and 15\% respectively; and finally, for ϵ2,0 = −0.04, we find 3.4\%, 0.15\%, and 0.14\%. From the relative errors for fiducial values closer to their ΛCDM limits, we find that most of the constraining power is lost. Our results highlight the importance of the constraining power from non-linear scales.",

keywords = "cosmology: theory, large-scale structure of Universe",

author = "\{EUCLID Consortium\} and N. Frusciante and F. Pace and Cardone, \{V. F.\} and S. Casas and I. Tutusaus and M. Ballardini and E. Bellini and G. Benevento and B. Bose and P. Valageas and N. Bartolo and P. Brax and Ferreira, \{P. G.\} and F. Finelli and K. Koyama and L. Legrand and L. Lombriser and D. Paoletti and M. Pietroni and A. Rozas-Fern{\'a}ndez and Z. Sakr and A. Silvestri and F. Vernizzi and Winther, \{H. A.\} and N. Aghanim and L. Amendola and N. Auricchio and R. Azzollini and M. Baldi and D. Bonino and E. Branchini and M. Brescia and J. Brinchmann and S. Camera and V. Capobianco and C. Carbone and J. Carretero and M. Castellano and S. Cavuoti and A. Cimatti and R. Cledassou and G. Congedo and L. Conversi and Y. Copin and L. Corcione and F. Courbin and M. Cropper and Silva, \{A. Da\} and H. Degaudenzi and J. Dinis and F. Dubath and X. Dupac and S. Dusini and S. Farrens and S. Ferriol and P. Fosalba and M. Frailis and E. Franceschi and S. Galeotta and B. Gillis and C. Giocoli and A. Grazian and F. Grupp and L. Guzzo and Haugan, \{S. V. H.\} and W. Holmes and F. Hormuth and A. Hornstrup and K. Jahnke and S. Kermiche and A. Kiessling and M. Kilbinger and T. Kitching and M. Kunz and H. Kurki-Suonio and S. Ligori and Lilje, \{P. B.\} and I. Lloro and E. Maiorano and O. Mansutti and O. Marggraf and K. Markovic and F. Marulli and R. Massey and E. Medinaceli and M. Meneghetti and G. Meylan and M. Moresco and L. Moscardini and E. Munari and Niemi, \{S. M.\} and J. Nightingale and C. Padilla and S. Paltani and F. Pasian and K. Pedersen and Percival, \{W. J.\} and V. Pettorino and G. Polenta and M. Poncet and L. Popa and F. Raison and R. Rebolo and A. Renzi and J. Rhodes and G. Riccio and E. Romelli and R. Saglia and D. Sapone and B. Sartoris and A. Secroun and G. Seidel and C. Sirignano and G. Sirri and L. Stanco and C. Surace and P. Tallada-Cresp{\'i} and Taylor, \{A. N.\} and I. Tereno and R. Toledo-Moreo and F. Torradeflot and Valentijn, \{E. A.\} and L. Valenziano and T. Vassallo and Kleijn, \{G. A. Verdoes\} and Y. Wang and A. Zacchei and G. Zamorani and J. Zoubian and V. Scottez",

note = "23 pages, 8 figures, 4 tables, 1 appendix, matches Journal version",

year = "2024",

month = oct,

day = "4",

doi = "10.1051/0004-6361/202347526",

language = "English",

volume = "690",

pages = "1--22",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

EUCLID Consortium, Frusciante, N, Pace, F, Cardone, VF, Casas, S, Tutusaus, I, Ballardini, M, Bellini, E, Benevento, G, Bose, B, Valageas, P, Bartolo, N, Brax, P, Ferreira, PG, Finelli, F, Koyama, K, Legrand, L, Lombriser, L, Paoletti, D, Pietroni, M, Rozas-Fernández, A, Sakr, Z, Silvestri, A, Vernizzi, F, Winther, HA, Aghanim, N, Amendola, L, Auricchio, N, Azzollini, R, Baldi, M, Bonino, D, Branchini, E, Brescia, M, Brinchmann, J, Camera, S, Capobianco, V, Carbone, C, Carretero, J, Castellano, M, Cavuoti, S, Cimatti, A, Cledassou, R, Congedo, G, Conversi, L, Copin, Y, Corcione, L, Courbin, F, Cropper, M, Silva, AD, Degaudenzi, H, Dinis, J, Dubath, F, Dupac, X, Dusini, S, Farrens, S, Ferriol, S, Fosalba, P, Frailis, M, Franceschi, E, Galeotta, S, Gillis, B, Giocoli, C, Grazian, A, Grupp, F, Guzzo, L, Haugan, SVH, Holmes, W, Hormuth, F, Hornstrup, A, Jahnke, K, Kermiche, S, Kiessling, A, Kilbinger, M, Kitching, T, Kunz, M, Kurki-Suonio, H, Ligori, S, Lilje, PB, Lloro, I, Maiorano, E, Mansutti, O, Marggraf, O, Markovic, K, Marulli, F, Massey, R, Medinaceli, E, Meneghetti, M, Meylan, G, Moresco, M, Moscardini, L, Munari, E, Niemi, SM, Nightingale, J, Padilla, C, Paltani, S, Pasian, F, Pedersen, K, Percival, WJ, Pettorino, V, Polenta, G, Poncet, M, Popa, L, Raison, F, Rebolo, R, Renzi, A, Rhodes, J, Riccio, G, Romelli, E, Saglia, R, Sapone, D, Sartoris, B, Secroun, A, Seidel, G, Sirignano, C, Sirri, G, Stanco, L, Surace, C, Tallada-Crespí, P, Taylor, AN, Tereno, I, Toledo-Moreo, R, Torradeflot, F, Valentijn, EA, Valenziano, L, Vassallo, T, Kleijn, GAV, Wang, Y, Zacchei, A, Zamorani, G, Zoubian, J & Scottez, V 2024, 'Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes', Astronomy and Astrophysics, vol. 690, A133, pp. 1-22. https://doi.org/10.1051/0004-6361/202347526

TY - JOUR

T1 - Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes

AU - EUCLID Consortium

AU - Frusciante, N.

AU - Pace, F.

AU - Cardone, V. F.

AU - Casas, S.

AU - Tutusaus, I.

AU - Ballardini, M.

AU - Bellini, E.

AU - Benevento, G.

AU - Bose, B.

AU - Valageas, P.

AU - Bartolo, N.

AU - Brax, P.

AU - Ferreira, P. G.

AU - Finelli, F.

AU - Koyama, K.

AU - Legrand, L.

AU - Lombriser, L.

AU - Paoletti, D.

AU - Pietroni, M.

AU - Rozas-Fernández, A.

AU - Sakr, Z.

AU - Silvestri, A.

AU - Vernizzi, F.

AU - Winther, H. A.

AU - Aghanim, N.

AU - Amendola, L.

AU - Auricchio, N.

AU - Azzollini, R.

AU - Baldi, M.

AU - Bonino, D.

AU - Branchini, E.

AU - Brescia, M.

AU - Brinchmann, J.

AU - Camera, S.

AU - Capobianco, V.

AU - Carbone, C.

AU - Carretero, J.

AU - Castellano, M.

AU - Cavuoti, S.

AU - Cimatti, A.

AU - Cledassou, R.

AU - Congedo, G.

AU - Conversi, L.

AU - Copin, Y.

AU - Corcione, L.

AU - Courbin, F.

AU - Cropper, M.

AU - Silva, A. Da

AU - Degaudenzi, H.

AU - Dinis, J.

AU - Dubath, F.

AU - Dupac, X.

AU - Dusini, S.

AU - Farrens, S.

AU - Ferriol, S.

AU - Fosalba, P.

AU - Frailis, M.

AU - Franceschi, E.

AU - Galeotta, S.

AU - Gillis, B.

AU - Giocoli, C.

AU - Grazian, A.

AU - Grupp, F.

AU - Guzzo, L.

AU - Haugan, S. V. H.

AU - Holmes, W.

AU - Hormuth, F.

AU - Hornstrup, A.

AU - Jahnke, K.

AU - Kermiche, S.

AU - Kiessling, A.

AU - Kilbinger, M.

AU - Kitching, T.

AU - Kunz, M.

AU - Kurki-Suonio, H.

AU - Ligori, S.

AU - Lilje, P. B.

AU - Lloro, I.

AU - Maiorano, E.

AU - Mansutti, O.

AU - Marggraf, O.

AU - Markovic, K.

AU - Marulli, F.

AU - Massey, R.

AU - Medinaceli, E.

AU - Meneghetti, M.

AU - Meylan, G.

AU - Moresco, M.

AU - Moscardini, L.

AU - Munari, E.

AU - Niemi, S. M.

AU - Nightingale, J.

AU - Padilla, C.

AU - Paltani, S.

AU - Pasian, F.

AU - Pedersen, K.

AU - Percival, W. J.

AU - Pettorino, V.

AU - Polenta, G.

AU - Poncet, M.

AU - Popa, L.

AU - Raison, F.

AU - Rebolo, R.

AU - Renzi, A.

AU - Rhodes, J.

AU - Riccio, G.

AU - Romelli, E.

AU - Saglia, R.

AU - Sapone, D.

AU - Sartoris, B.

AU - Secroun, A.

AU - Seidel, G.

AU - Sirignano, C.

AU - Sirri, G.

AU - Stanco, L.

AU - Surace, C.

AU - Tallada-Crespí, P.

AU - Taylor, A. N.

AU - Tereno, I.

AU - Toledo-Moreo, R.

AU - Torradeflot, F.

AU - Valentijn, E. A.

AU - Valenziano, L.

AU - Vassallo, T.

AU - Kleijn, G. A. Verdoes

AU - Wang, Y.

AU - Zacchei, A.

AU - Zamorani, G.

AU - Zoubian, J.

AU - Scottez, V.

N1 - 23 pages, 8 figures, 4 tables, 1 appendix, matches Journal version

PY - 2024/10/4

Y1 - 2024/10/4

N2 - Context. The future Euclid space satellite mission will offer an invaluable opportunity to constrain modifications to Einstein’s general relativity at cosmic scales. In this paper, we focus on modified gravity models characterised, at linear scales, by a scale-independent growth of perturbations while featuring different testable types of derivative screening mechanisms at smaller non-linear scales. Aims. We considered three specific models, namely Jordan-Brans-Dicke, a scalar-tensor theory with a flat potential, the normal branch of Dvali-Gabadadze-Porrati (nDGP) gravity, a braneworld model in which our Universe is a four-dimensional brane embedded in a five-dimensional Minkowski space-time, and k-mouflage gravity, an extension of k-essence scenarios with a universal coupling of the scalar field to matter. In preparation for real data, we provide forecasts from spectroscopic and photometric primary probes by Euclid on the cosmological parameters and the additional parameters of the models, respectively, ωBD, Ωгc and ϵ2,0, which quantify the deviations from general relativity. This analysis will improve our knowledge of the cosmology of these modified gravity models. Methods. The forecast analysis employs the Fisher matrix method applied to weak lensing (WL); photometric galaxy clustering (GCph), spectroscopic galaxy clustering (GCsp) and the cross-correlation (XC) between GCph and WL. For the Euclid survey specifications, we define three scenarios that are characterised by different cuts in the maximum multipole and wave number, to assess the constraining power of non-linear scales. For each model we considered two fiducial values for the corresponding model parameter. Results. In an optimistic setting at 68.3% confidence interval, we find the following percentage relative errors with Euclid alone: for log10 ωBD, with a fiducial value of ωBD = 800, 27.1% using GCsp alone, 3.6% using GCph+WL+XC and 3.2% using GCph+WL+XC+GCsp; for log10 Ωгc, with a fiducial value of Ωгc = 0.25, we find 93.4, 20 and 15% respectively; and finally, for ϵ2,0 = −0.04, we find 3.4%, 0.15%, and 0.14%. From the relative errors for fiducial values closer to their ΛCDM limits, we find that most of the constraining power is lost. Our results highlight the importance of the constraining power from non-linear scales.

AB - Context. The future Euclid space satellite mission will offer an invaluable opportunity to constrain modifications to Einstein’s general relativity at cosmic scales. In this paper, we focus on modified gravity models characterised, at linear scales, by a scale-independent growth of perturbations while featuring different testable types of derivative screening mechanisms at smaller non-linear scales. Aims. We considered three specific models, namely Jordan-Brans-Dicke, a scalar-tensor theory with a flat potential, the normal branch of Dvali-Gabadadze-Porrati (nDGP) gravity, a braneworld model in which our Universe is a four-dimensional brane embedded in a five-dimensional Minkowski space-time, and k-mouflage gravity, an extension of k-essence scenarios with a universal coupling of the scalar field to matter. In preparation for real data, we provide forecasts from spectroscopic and photometric primary probes by Euclid on the cosmological parameters and the additional parameters of the models, respectively, ωBD, Ωгc and ϵ2,0, which quantify the deviations from general relativity. This analysis will improve our knowledge of the cosmology of these modified gravity models. Methods. The forecast analysis employs the Fisher matrix method applied to weak lensing (WL); photometric galaxy clustering (GCph), spectroscopic galaxy clustering (GCsp) and the cross-correlation (XC) between GCph and WL. For the Euclid survey specifications, we define three scenarios that are characterised by different cuts in the maximum multipole and wave number, to assess the constraining power of non-linear scales. For each model we considered two fiducial values for the corresponding model parameter. Results. In an optimistic setting at 68.3% confidence interval, we find the following percentage relative errors with Euclid alone: for log10 ωBD, with a fiducial value of ωBD = 800, 27.1% using GCsp alone, 3.6% using GCph+WL+XC and 3.2% using GCph+WL+XC+GCsp; for log10 Ωгc, with a fiducial value of Ωгc = 0.25, we find 93.4, 20 and 15% respectively; and finally, for ϵ2,0 = −0.04, we find 3.4%, 0.15%, and 0.14%. From the relative errors for fiducial values closer to their ΛCDM limits, we find that most of the constraining power is lost. Our results highlight the importance of the constraining power from non-linear scales.

KW - cosmology: theory

KW - large-scale structure of Universe

U2 - 10.1051/0004-6361/202347526

DO - 10.1051/0004-6361/202347526

M3 - Article

SN - 0004-6361

VL - 690

SP - 1

EP - 22

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A133

ER -

Euclid: Constraining linearly scale-independent modifications of gravity with the spectroscopic and photometric primary probes

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Novel Non-linear Techniques for Cosmic Large Scale Structure

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