Exploring cosmic origins with CORE: Survey requirements and mission design

J. Delabrouille; P. De Bernardis; F. R. Bouchet; A. Achúcarro; P. A.R. Ade; R. Allison; F. Arroja; E. Artal; M. Ashdown; C. Baccigalupi; M. Ballardini; A. J. Banday; R. Banerji; D. Barbosa; J. Bartlett; N. Bartolo; S. Basak; J. J.A. Baselmans; K. Basu; E. S. Battistelli; R. Battye; D. Baumann; A. Benoít; M. Bersanelli; A. Bideaud; M. Biesiada; M. Bilicki; A. Bonaldi; M. Bonato; J. Borrill; F. Boulanger; T. Brinckmann; M. L. Brown; M. Bucher; C. Burigana; A. Buzzelli; G. Cabass; Z. Y. Cai; M. Calvo; A. Caputo; C. S. Carvalho; F. J. Casas; G. Castellano; A. Catalano; A. Challinor; I. Charles; J. Chluba; D. L. Clements; S. Clesse; S. Colafrancesco; I. Colantoni; D. Contreras; A. Coppolecchia; M. Crook; G. D'Alessandro; G. D'Amico; A. Da Silva; M. De Avillez; G. De Gasperis; M. De Petris; G. De Zotti; L. Danese; F. X. Désert; V. Desjacques; E. Di Valentino; C. Dickinson; J. M. Diego; S. Doyle; R. Durrer; C. Dvorkin; H. K. Eriksen; J. Errard; S. Feeney; R. Fernández-Cobos; F. Finelli; F. Forastieri; C. Franceschet; U. Fuskeland; S. Galli; R. T. Génova-Santos; M. Gerbino; E. Giusarma; A. Gomez; J. González-Nuevo; S. Grandis; J. Greenslade; J. Goupy; S. Hagstotz; S. Hanany; W. Handley; S. Henrot-Versillé; C. Hernández-Monteagudo; C. Hervias-Caimapo; M. Hills; M. Hindmarsh; E. Hivon; D. T. Hoang; D. C. Hooper; B. Hu; E. Keihänen; R. Keskitalo; K. Kiiveri; T. Kisner; T. Kitching; M. Kunz; H. Kurki-Suonio; G. Lagache; L. Lamagna; A. Lapi; A. Lasenby; M. Lattanzi; A. M.C.Le Brun; J. Lesgourgues; M. Liguori; V. Lindholm; J. Lizarraga; G. Luzzi; F. Randy; B. Maffei; N. Mandolesi; S. Martin; E. Martinez-Gonzalez; C. J.A.P. Martins; S. Masi; M. Massardi; S. Matarrese; P. Mazzotta; D. McCarthy; A. Melchiorri; J. B. Melin; A. Mennella; J. Mohr; D. Molinari; A. Monfardini; L. Montier; P. Natoli; M. Negrello; A. Notari; F. Noviello; F. Oppizzi; C. O'Sullivan; L. Pagano; A. Paiella; E. Pajer; D. Paoletti; S. Paradiso; R. B. Partridge; G. Patanchon; S. P. Patil; O. Perdereau; F. Piacentini; M. Piat; G. Pisano; L. Polastri; G. Polenta; A. Pollo; N. Ponthieu; V. Poulin; D. Prêle; M. Quartin; A. Ravenni; M. Remazeilles; A. Renzi; C. Ringeval; D. Roest; M. Roman; B. F. Roukema; J. A. Rubiño-Martin; L. Salvati; D. Scott; S. Serjeant; G. Signorelli; A. A. Starobinsky; R. Sunyaev; C. Y. Tan; A. Tartari; G. Tasinato; L. Toffolatti; M. Tomasi; J. Torrado; D. Tramonte; N. Trappe; S. Triqueneaux; M. Tristram; T. Trombetti; M. Tucci; C. Tucker; J. Urrestilla; J. Väliviita; R. Van De Weygaert; B. Van Tent; V. Vennin; L. Verde; G. Vermeulen; P. Vielva; N. Vittorio; F. Voisin; C. Wallis; B. Wandelt; I. K. Wehus; J. Weller; K. Young; M. Zannoni

doi:10.1088/1475-7516/2018/04/014

Exploring cosmic origins with CORE: Survey requirements and mission design

J. Delabrouille^*
, P. De Bernardis
, F. R. Bouchet
, A. Achúcarro
, P. A.R. Ade
, R. Allison
, F. Arroja
, E. Artal
, M. Ashdown
, C. Baccigalupi
, M. Ballardini
, A. J. Banday
, R. Banerji
, D. Barbosa
, J. Bartlett
, N. Bartolo
, S. Basak
, J. J.A. Baselmans
, K. Basu
, E. S. Battistelli

R. Battye, D. Baumann, A. Benoít, M. Bersanelli, A. Bideaud, M. Biesiada, M. Bilicki, A. Bonaldi, M. Bonato, J. Borrill, F. Boulanger, T. Brinckmann, M. L. Brown, M. Bucher, C. Burigana, A. Buzzelli, G. Cabass, Z. Y. Cai, M. Calvo, A. Caputo, C. S. Carvalho, F. J. Casas, G. Castellano, A. Catalano, A. Challinor, I. Charles, J. Chluba, D. L. Clements, S. Clesse, S. Colafrancesco, I. Colantoni, D. Contreras, A. Coppolecchia, M. Crook, G. D'Alessandro, G. D'Amico, A. Da Silva, M. De Avillez, G. De Gasperis, M. De Petris, G. De Zotti, L. Danese, F. X. Désert, V. Desjacques, E. Di Valentino, C. Dickinson, J. M. Diego, S. Doyle, R. Durrer, C. Dvorkin, H. K. Eriksen, J. Errard, S. Feeney, R. Fernández-Cobos, F. Finelli, F. Forastieri, C. Franceschet, U. Fuskeland, S. Galli, R. T. Génova-Santos, M. Gerbino, E. Giusarma, A. Gomez, J. González-Nuevo, S. Grandis, J. Greenslade, J. Goupy, S. Hagstotz, S. Hanany, W. Handley, S. Henrot-Versillé, C. Hernández-Monteagudo, C. Hervias-Caimapo, M. Hills, M. Hindmarsh, E. Hivon, D. T. Hoang, D. C. Hooper, B. Hu, E. Keihänen, R. Keskitalo, K. Kiiveri, T. Kisner, T. Kitching, M. Kunz, H. Kurki-Suonio, G. Lagache, L. Lamagna, A. Lapi, A. Lasenby, M. Lattanzi, A. M.C.Le Brun, J. Lesgourgues, M. Liguori, V. Lindholm, J. Lizarraga, G. Luzzi, F. Randy, B. Maffei, N. Mandolesi, S. Martin, E. Martinez-Gonzalez, C. J.A.P. Martins, S. Masi, M. Massardi, S. Matarrese, P. Mazzotta, D. McCarthy, A. Melchiorri, J. B. Melin, A. Mennella, J. Mohr, D. Molinari, A. Monfardini, L. Montier, P. Natoli, M. Negrello, A. Notari, F. Noviello, F. Oppizzi, C. O'Sullivan, L. Pagano, A. Paiella, E. Pajer, D. Paoletti, S. Paradiso, R. B. Partridge, G. Patanchon, S. P. Patil, O. Perdereau, F. Piacentini, M. Piat, G. Pisano, L. Polastri, G. Polenta, A. Pollo, N. Ponthieu, V. Poulin, D. Prêle, M. Quartin, A. Ravenni, M. Remazeilles, A. Renzi, C. Ringeval, D. Roest, M. Roman, B. F. Roukema, J. A. Rubiño-Martin, L. Salvati, D. Scott, S. Serjeant, G. Signorelli, A. A. Starobinsky, R. Sunyaev, C. Y. Tan, A. Tartari, G. Tasinato, L. Toffolatti, M. Tomasi, J. Torrado, D. Tramonte, N. Trappe, S. Triqueneaux, M. Tristram, T. Trombetti, M. Tucci, C. Tucker, J. Urrestilla, J. Väliviita, R. Van De Weygaert, B. Van Tent, V. Vennin, L. Verde, G. Vermeulen, P. Vielva, N. Vittorio, F. Voisin, C. Wallis, B. Wandelt, I. K. Wehus, J. Weller, K. Young, M. Zannoni

^*Corresponding author for this work

APC - AstroParticule et Cosmologie
University of Rome La Sapienza
National Institute for Nuclear Physics
Sorbonne Université
Leiden University
University of the Basque Country
Cardiff University
University of Cambridge
National Taiwan University
Universidad de Cantabria
International School for Advanced Studies
University of Bologna
Istituto di Astrofisica Spaziale e Fisica Cosmica di Bologna
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University of Padua
Astronomical Observatory of Padua
Amrita Vishwa Vidyapeetham
SRON Netherlands Institute for Space Research
University of Bonn
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Université Grenoble Alpes
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University of Ferrara
University of Rome Tor Vergata
University of Science and Technology of China
University of Lisbon
Instituto de Física de Cantabria
National Research Council of Italy
Imperial College London
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University of Minnesota Twin Cities
Université Paris-Sud
Centro de Estudios de Física del Cosmos de Aragón (CEFCA)
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University of Helsinki
Vietnamese Academy of Science and Technology
Beijing Normal University
University of Barcelona
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Aix Marseille Université
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Laboratoire de Physique Nucléaire et de Hautes Energies
École normale supérieure de Lyon
Nicolaus Copernicus University in Toruń
Open University Milton Keynes
RAS - Landau Institute for Theoretical Physics
Joint Institute for Nuclear Research
Max Planck Institute for Astrophysics
RAS - Space Research Institute
Swansea University
Université Paris-Sud
University of Portsmouth
ICREA
University of Milan - Bicocca

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

152 Citations (Scopus)

Abstract

Future observations of cosmic microwave background (CMB) polarisation have the potential to answer some of the most fundamental questions of modern physics and cosmology, including: what physical process gave birth to the Universe we see today? What are the dark matter and dark energy that seem to constitute 95% of the energy density of the Universe? Do we need extensions to the standard model of particle physics and fundamental interactions? Is the ΛCDM cosmological scenario correct, or are we missing an essential piece of the puzzle? In this paper, we list the requirements for a future CMB polarisation survey addressing these scientific objectives, and discuss the design drivers of the COREmfive space mission proposed to ESA in answer to the "M5" call for a medium-sized mission. The rationale and options, and the methodologies used to assess the mission's performance, are of interest to other future CMB mission design studies. COREmfive has 19 frequency channels, distributed over a broad frequency range, spanning the 60-600 GHz interval, to control astrophysical foreground emission. The angular resolution ranges from 2^′ to 18^′, and the aggregate CMB sensitivity is about 2 μKċarcmin. The observations are made with a single integrated focal-plane instrument, consisting of an array of 2100 cryogenically-cooled, linearly-polarised detectors at the focus of a 1.2-m aperture cross-Dragone telescope. The mission is designed to minimise all sources of systematic effects, which must be controlled so that no more than 10^-4 of the intensity leaks into polarisation maps, and no more than about 1% of E-type polarisation leaks into B-type modes. COREmfive observes the sky from a large Lissajous orbit around the Sun-Earth L2 point on an orbit that offers stable observing conditions and avoids contamination from sidelobe pick-up of stray radiation originating from the Sun, Earth, and Moon. The entire sky is observed repeatedly during four years of continuous scanning, with a combination of three rotations of the spacecraft over different timescales. With about 50% of the sky covered every few days, this scan strategy provides the mitigation of systematic effects and the internal redundancy that are needed to convincingly extract the primordial B-mode signal on large angular scales, and check with adequate sensitivity the consistency of the observations in several independent data subsets. COREmfive is designed as a "near-ultimate" CMB polarisation mission which, for optimal complementarity with ground-based observations, will perform the observations that are known to be essential to CMB polarisation science and cannot be obtained by any other means than a dedicated space mission. It will provide well-characterised, highly-redundant multi-frequency observations of polarisation at all the scales where foreground emission and cosmic variance dominate the final uncertainty for obtaining precision CMB science, as well as 2^′ angular resolution maps of high-frequency foreground emission in the 300-600 GHz frequency range, essential for complementarity with future ground-based observations with large telescopes that can observe the CMB with the same beamsize.

Original language	English
Article number	014
Journal	Journal of Cosmology and Astroparticle Physics
Volume	2018
Issue number	4
DOIs	https://doi.org/10.1088/1475-7516/2018/04/014
Publication status	Published - 5 Apr 2018
Externally published	Yes

Keywords

CMBR experiments
CMBR polarization
gravitational lensing
physics of the early universe

Access to Document

10.1088/1475-7516/2018/04/014

Cite this

Delabrouille, J., De Bernardis, P., Bouchet, F. R., Achúcarro, A., Ade, P. A. R., Allison, R., Arroja, F., Artal, E., Ashdown, M., Baccigalupi, C., Ballardini, M., Banday, A. J., Banerji, R., Barbosa, D., Bartlett, J., Bartolo, N., Basak, S., Baselmans, J. J. A., Basu, K., ... Zannoni, M. (2018). Exploring cosmic origins with CORE: Survey requirements and mission design. Journal of Cosmology and Astroparticle Physics, 2018(4), Article 014. https://doi.org/10.1088/1475-7516/2018/04/014

@article{a623472c4d9543c884c888b231717c40,

title = "Exploring cosmic origins with CORE: Survey requirements and mission design",

abstract = "Future observations of cosmic microwave background (CMB) polarisation have the potential to answer some of the most fundamental questions of modern physics and cosmology, including: what physical process gave birth to the Universe we see today? What are the dark matter and dark energy that seem to constitute 95\% of the energy density of the Universe? Do we need extensions to the standard model of particle physics and fundamental interactions? Is the ΛCDM cosmological scenario correct, or are we missing an essential piece of the puzzle? In this paper, we list the requirements for a future CMB polarisation survey addressing these scientific objectives, and discuss the design drivers of the COREmfive space mission proposed to ESA in answer to the {"}M5{"} call for a medium-sized mission. The rationale and options, and the methodologies used to assess the mission's performance, are of interest to other future CMB mission design studies. COREmfive has 19 frequency channels, distributed over a broad frequency range, spanning the 60-600 GHz interval, to control astrophysical foreground emission. The angular resolution ranges from 2′ to 18′, and the aggregate CMB sensitivity is about 2 μKċarcmin. The observations are made with a single integrated focal-plane instrument, consisting of an array of 2100 cryogenically-cooled, linearly-polarised detectors at the focus of a 1.2-m aperture cross-Dragone telescope. The mission is designed to minimise all sources of systematic effects, which must be controlled so that no more than 10-4 of the intensity leaks into polarisation maps, and no more than about 1\% of E-type polarisation leaks into B-type modes. COREmfive observes the sky from a large Lissajous orbit around the Sun-Earth L2 point on an orbit that offers stable observing conditions and avoids contamination from sidelobe pick-up of stray radiation originating from the Sun, Earth, and Moon. The entire sky is observed repeatedly during four years of continuous scanning, with a combination of three rotations of the spacecraft over different timescales. With about 50\% of the sky covered every few days, this scan strategy provides the mitigation of systematic effects and the internal redundancy that are needed to convincingly extract the primordial B-mode signal on large angular scales, and check with adequate sensitivity the consistency of the observations in several independent data subsets. COREmfive is designed as a {"}near-ultimate{"} CMB polarisation mission which, for optimal complementarity with ground-based observations, will perform the observations that are known to be essential to CMB polarisation science and cannot be obtained by any other means than a dedicated space mission. It will provide well-characterised, highly-redundant multi-frequency observations of polarisation at all the scales where foreground emission and cosmic variance dominate the final uncertainty for obtaining precision CMB science, as well as 2′ angular resolution maps of high-frequency foreground emission in the 300-600 GHz frequency range, essential for complementarity with future ground-based observations with large telescopes that can observe the CMB with the same beamsize.",

keywords = "CMBR experiments, CMBR polarization, gravitational lensing, physics of the early universe",

author = "J. Delabrouille and \{De Bernardis\}, P. and Bouchet, \{F. R.\} and A. Ach{\'u}carro and Ade, \{P. A.R.\} and R. Allison and F. Arroja and E. Artal and M. Ashdown and C. Baccigalupi and M. Ballardini and Banday, \{A. J.\} and R. Banerji and D. Barbosa and J. Bartlett and N. Bartolo and S. Basak and Baselmans, \{J. J.A.\} and K. Basu and Battistelli, \{E. S.\} and R. Battye and D. Baumann and A. Beno{\'i}t and M. Bersanelli and A. Bideaud and M. Biesiada and M. Bilicki and A. Bonaldi and M. Bonato and J. Borrill and F. Boulanger and T. Brinckmann and Brown, \{M. L.\} and M. Bucher and C. Burigana and A. Buzzelli and G. Cabass and Cai, \{Z. Y.\} and M. Calvo and A. Caputo and Carvalho, \{C. S.\} and Casas, \{F. J.\} and G. Castellano and A. Catalano and A. Challinor and I. Charles and J. Chluba and Clements, \{D. L.\} and S. Clesse and S. Colafrancesco and I. Colantoni and D. Contreras and A. Coppolecchia and M. Crook and G. D'Alessandro and G. D'Amico and Silva, \{A. Da\} and \{De Avillez\}, M. and \{De Gasperis\}, G. and Petris, \{M. De\} and \{De Zotti\}, G. and L. Danese and D{\'e}sert, \{F. X.\} and V. Desjacques and Valentino, \{E. Di\} and C. Dickinson and Diego, \{J. M.\} and S. Doyle and R. Durrer and C. Dvorkin and Eriksen, \{H. K.\} and J. Errard and S. Feeney and R. Fern{\'a}ndez-Cobos and F. Finelli and F. Forastieri and C. Franceschet and U. Fuskeland and S. Galli and G{\'e}nova-Santos, \{R. T.\} and M. Gerbino and E. Giusarma and A. Gomez and J. Gonz{\'a}lez-Nuevo and S. Grandis and J. Greenslade and J. Goupy and S. Hagstotz and S. Hanany and W. Handley and S. Henrot-Versill{\'e} and C. Hern{\'a}ndez-Monteagudo and C. Hervias-Caimapo and M. Hills and M. Hindmarsh and E. Hivon and Hoang, \{D. T.\} and Hooper, \{D. C.\} and B. Hu and E. Keih{\"a}nen and R. Keskitalo and K. Kiiveri and T. Kisner and T. Kitching and M. Kunz and H. Kurki-Suonio and G. Lagache and L. Lamagna and A. Lapi and A. Lasenby and M. Lattanzi and Brun, \{A. M.C.Le\} and J. Lesgourgues and M. Liguori and V. Lindholm and J. Lizarraga and G. Luzzi and F. Randy and B. Maffei and N. Mandolesi and S. Martin and E. Martinez-Gonzalez and Martins, \{C. J.A.P.\} and S. Masi and M. Massardi and S. Matarrese and P. Mazzotta and D. McCarthy and A. Melchiorri and Melin, \{J. B.\} and A. Mennella and J. Mohr and D. Molinari and A. Monfardini and L. Montier and P. Natoli and M. Negrello and A. Notari and F. Noviello and F. Oppizzi and C. O'Sullivan and L. Pagano and A. Paiella and E. Pajer and D. Paoletti and S. Paradiso and Partridge, \{R. B.\} and G. Patanchon and Patil, \{S. P.\} and O. Perdereau and F. Piacentini and M. Piat and G. Pisano and L. Polastri and G. Polenta and A. Pollo and N. Ponthieu and V. Poulin and D. Pr{\^e}le and M. Quartin and A. Ravenni and M. Remazeilles and A. Renzi and C. Ringeval and D. Roest and M. Roman and Roukema, \{B. F.\} and Rubi{\~n}o-Martin, \{J. A.\} and L. Salvati and D. Scott and S. Serjeant and G. Signorelli and Starobinsky, \{A. A.\} and R. Sunyaev and Tan, \{C. Y.\} and A. Tartari and G. Tasinato and L. Toffolatti and M. Tomasi and J. Torrado and D. Tramonte and N. Trappe and S. Triqueneaux and M. Tristram and T. Trombetti and M. Tucci and C. Tucker and J. Urrestilla and J. V{\"a}liviita and \{De Weygaert\}, \{R. Van\} and Tent, \{B. Van\} and V. Vennin and L. Verde and G. Vermeulen and P. Vielva and N. Vittorio and F. Voisin and C. Wallis and B. Wandelt and Wehus, \{I. K.\} and J. Weller and K. Young and M. Zannoni",

note = "Publisher Copyright: {\textcopyright} 2018 IOP Publishing Ltd and Sissa Medialab.",

year = "2018",

month = apr,

day = "5",

doi = "10.1088/1475-7516/2018/04/014",

language = "English",

volume = "2018",

journal = "Journal of Cosmology and Astroparticle Physics",

issn = "1475-7516",

number = "4",

}

Delabrouille, J, De Bernardis, P, Bouchet, FR, Achúcarro, A, Ade, PAR, Allison, R, Arroja, F, Artal, E, Ashdown, M, Baccigalupi, C, Ballardini, M, Banday, AJ, Banerji, R, Barbosa, D, Bartlett, J, Bartolo, N, Basak, S, Baselmans, JJA, Basu, K, Battistelli, ES, Battye, R, Baumann, D, Benoít, A, Bersanelli, M, Bideaud, A, Biesiada, M, Bilicki, M, Bonaldi, A, Bonato, M, Borrill, J, Boulanger, F, Brinckmann, T, Brown, ML, Bucher, M, Burigana, C, Buzzelli, A, Cabass, G, Cai, ZY, Calvo, M, Caputo, A, Carvalho, CS, Casas, FJ, Castellano, G, Catalano, A, Challinor, A, Charles, I, Chluba, J, Clements, DL, Clesse, S, Colafrancesco, S, Colantoni, I, Contreras, D, Coppolecchia, A, Crook, M, D'Alessandro, G, D'Amico, G, Silva, AD, De Avillez, M, De Gasperis, G, Petris, MD, De Zotti, G, Danese, L, Désert, FX, Desjacques, V, Valentino, ED, Dickinson, C, Diego, JM, Doyle, S, Durrer, R, Dvorkin, C, Eriksen, HK, Errard, J, Feeney, S, Fernández-Cobos, R, Finelli, F, Forastieri, F, Franceschet, C, Fuskeland, U, Galli, S, Génova-Santos, RT, Gerbino, M, Giusarma, E, Gomez, A, González-Nuevo, J, Grandis, S, Greenslade, J, Goupy, J, Hagstotz, S, Hanany, S, Handley, W, Henrot-Versillé, S, Hernández-Monteagudo, C, Hervias-Caimapo, C, Hills, M, Hindmarsh, M, Hivon, E, Hoang, DT, Hooper, DC, Hu, B, Keihänen, E, Keskitalo, R, Kiiveri, K, Kisner, T, Kitching, T, Kunz, M, Kurki-Suonio, H, Lagache, G, Lamagna, L, Lapi, A, Lasenby, A, Lattanzi, M, Brun, AMCL, Lesgourgues, J, Liguori, M, Lindholm, V, Lizarraga, J, Luzzi, G, Randy, F, Maffei, B, Mandolesi, N, Martin, S, Martinez-Gonzalez, E, Martins, CJAP, Masi, S, Massardi, M, Matarrese, S, Mazzotta, P, McCarthy, D, Melchiorri, A, Melin, JB, Mennella, A, Mohr, J, Molinari, D, Monfardini, A, Montier, L, Natoli, P, Negrello, M, Notari, A, Noviello, F, Oppizzi, F, O'Sullivan, C, Pagano, L, Paiella, A, Pajer, E, Paoletti, D, Paradiso, S, Partridge, RB, Patanchon, G, Patil, SP, Perdereau, O, Piacentini, F, Piat, M, Pisano, G, Polastri, L, Polenta, G, Pollo, A, Ponthieu, N, Poulin, V, Prêle, D, Quartin, M, Ravenni, A, Remazeilles, M, Renzi, A, Ringeval, C, Roest, D, Roman, M, Roukema, BF, Rubiño-Martin, JA, Salvati, L, Scott, D, Serjeant, S, Signorelli, G, Starobinsky, AA, Sunyaev, R, Tan, CY, Tartari, A, Tasinato, G, Toffolatti, L, Tomasi, M, Torrado, J, Tramonte, D, Trappe, N, Triqueneaux, S, Tristram, M, Trombetti, T, Tucci, M, Tucker, C, Urrestilla, J, Väliviita, J, De Weygaert, RV, Tent, BV, Vennin, V, Verde, L, Vermeulen, G, Vielva, P, Vittorio, N, Voisin, F, Wallis, C, Wandelt, B, Wehus, IK, Weller, J, Young, K & Zannoni, M 2018, 'Exploring cosmic origins with CORE: Survey requirements and mission design', Journal of Cosmology and Astroparticle Physics, vol. 2018, no. 4, 014. https://doi.org/10.1088/1475-7516/2018/04/014

TY - JOUR

T1 - Exploring cosmic origins with CORE

T2 - Survey requirements and mission design

AU - Delabrouille, J.

AU - De Bernardis, P.

AU - Bouchet, F. R.

AU - Achúcarro, A.

AU - Ade, P. A.R.

AU - Allison, R.

AU - Arroja, F.

AU - Artal, E.

AU - Ashdown, M.

AU - Baccigalupi, C.

AU - Ballardini, M.

AU - Banday, A. J.

AU - Banerji, R.

AU - Barbosa, D.

AU - Bartlett, J.

AU - Bartolo, N.

AU - Basak, S.

AU - Baselmans, J. J.A.

AU - Basu, K.

AU - Battistelli, E. S.

AU - Battye, R.

AU - Baumann, D.

AU - Benoít, A.

AU - Bersanelli, M.

AU - Bideaud, A.

AU - Biesiada, M.

AU - Bilicki, M.

AU - Bonaldi, A.

AU - Bonato, M.

AU - Borrill, J.

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PY - 2018/4/5

Y1 - 2018/4/5

N2 - Future observations of cosmic microwave background (CMB) polarisation have the potential to answer some of the most fundamental questions of modern physics and cosmology, including: what physical process gave birth to the Universe we see today? What are the dark matter and dark energy that seem to constitute 95% of the energy density of the Universe? Do we need extensions to the standard model of particle physics and fundamental interactions? Is the ΛCDM cosmological scenario correct, or are we missing an essential piece of the puzzle? In this paper, we list the requirements for a future CMB polarisation survey addressing these scientific objectives, and discuss the design drivers of the COREmfive space mission proposed to ESA in answer to the "M5" call for a medium-sized mission. The rationale and options, and the methodologies used to assess the mission's performance, are of interest to other future CMB mission design studies. COREmfive has 19 frequency channels, distributed over a broad frequency range, spanning the 60-600 GHz interval, to control astrophysical foreground emission. The angular resolution ranges from 2′ to 18′, and the aggregate CMB sensitivity is about 2 μKċarcmin. The observations are made with a single integrated focal-plane instrument, consisting of an array of 2100 cryogenically-cooled, linearly-polarised detectors at the focus of a 1.2-m aperture cross-Dragone telescope. The mission is designed to minimise all sources of systematic effects, which must be controlled so that no more than 10-4 of the intensity leaks into polarisation maps, and no more than about 1% of E-type polarisation leaks into B-type modes. COREmfive observes the sky from a large Lissajous orbit around the Sun-Earth L2 point on an orbit that offers stable observing conditions and avoids contamination from sidelobe pick-up of stray radiation originating from the Sun, Earth, and Moon. The entire sky is observed repeatedly during four years of continuous scanning, with a combination of three rotations of the spacecraft over different timescales. With about 50% of the sky covered every few days, this scan strategy provides the mitigation of systematic effects and the internal redundancy that are needed to convincingly extract the primordial B-mode signal on large angular scales, and check with adequate sensitivity the consistency of the observations in several independent data subsets. COREmfive is designed as a "near-ultimate" CMB polarisation mission which, for optimal complementarity with ground-based observations, will perform the observations that are known to be essential to CMB polarisation science and cannot be obtained by any other means than a dedicated space mission. It will provide well-characterised, highly-redundant multi-frequency observations of polarisation at all the scales where foreground emission and cosmic variance dominate the final uncertainty for obtaining precision CMB science, as well as 2′ angular resolution maps of high-frequency foreground emission in the 300-600 GHz frequency range, essential for complementarity with future ground-based observations with large telescopes that can observe the CMB with the same beamsize.

AB - Future observations of cosmic microwave background (CMB) polarisation have the potential to answer some of the most fundamental questions of modern physics and cosmology, including: what physical process gave birth to the Universe we see today? What are the dark matter and dark energy that seem to constitute 95% of the energy density of the Universe? Do we need extensions to the standard model of particle physics and fundamental interactions? Is the ΛCDM cosmological scenario correct, or are we missing an essential piece of the puzzle? In this paper, we list the requirements for a future CMB polarisation survey addressing these scientific objectives, and discuss the design drivers of the COREmfive space mission proposed to ESA in answer to the "M5" call for a medium-sized mission. The rationale and options, and the methodologies used to assess the mission's performance, are of interest to other future CMB mission design studies. COREmfive has 19 frequency channels, distributed over a broad frequency range, spanning the 60-600 GHz interval, to control astrophysical foreground emission. The angular resolution ranges from 2′ to 18′, and the aggregate CMB sensitivity is about 2 μKċarcmin. The observations are made with a single integrated focal-plane instrument, consisting of an array of 2100 cryogenically-cooled, linearly-polarised detectors at the focus of a 1.2-m aperture cross-Dragone telescope. The mission is designed to minimise all sources of systematic effects, which must be controlled so that no more than 10-4 of the intensity leaks into polarisation maps, and no more than about 1% of E-type polarisation leaks into B-type modes. COREmfive observes the sky from a large Lissajous orbit around the Sun-Earth L2 point on an orbit that offers stable observing conditions and avoids contamination from sidelobe pick-up of stray radiation originating from the Sun, Earth, and Moon. The entire sky is observed repeatedly during four years of continuous scanning, with a combination of three rotations of the spacecraft over different timescales. With about 50% of the sky covered every few days, this scan strategy provides the mitigation of systematic effects and the internal redundancy that are needed to convincingly extract the primordial B-mode signal on large angular scales, and check with adequate sensitivity the consistency of the observations in several independent data subsets. COREmfive is designed as a "near-ultimate" CMB polarisation mission which, for optimal complementarity with ground-based observations, will perform the observations that are known to be essential to CMB polarisation science and cannot be obtained by any other means than a dedicated space mission. It will provide well-characterised, highly-redundant multi-frequency observations of polarisation at all the scales where foreground emission and cosmic variance dominate the final uncertainty for obtaining precision CMB science, as well as 2′ angular resolution maps of high-frequency foreground emission in the 300-600 GHz frequency range, essential for complementarity with future ground-based observations with large telescopes that can observe the CMB with the same beamsize.

KW - CMBR experiments

KW - CMBR polarization

KW - gravitational lensing

KW - physics of the early universe

UR - https://www.scopus.com/pages/publications/85047556422

U2 - 10.1088/1475-7516/2018/04/014

DO - 10.1088/1475-7516/2018/04/014

M3 - Article

AN - SCOPUS:85047556422

SN - 1475-7516

VL - 2018

JO - Journal of Cosmology and Astroparticle Physics

JF - Journal of Cosmology and Astroparticle Physics

IS - 4

M1 - 014

ER -

Exploring cosmic origins with CORE: Survey requirements and mission design

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