Microwave spectro-polarimetry of matter and radiation across space and time

Delabrouille, J.; Abitbol, Maximilian H.; Aghanim, N.; Ali-Haı̈moud, Yacine; Alonso, David; Alvarez, Marcelo A.; Banday, A. J.; Bartlett, J. G.; Baselmans, Jochem; Basu, Kaustuv; Battaglia, Nicholas; Climent, José Ramón Bermejo; Bernal, José Luís; Béthermin, M.; Bolliet, Boris; Bonato, M.; Bouchet, F. R.; Breysse, Patrick C.; Burigana, C.; Cai, Zhen; Chluba, Jens; Churazov, E.; Dannerbauer, H.; Bernardis, P. de; Zotti, G. de; Valentino, Eleonora Di; Dimastrogiovanni, Emanuela; Endo, Akira; Erler, Jens; Ferraro, Simone; Finelli⋆, F.; Fixsen, D. J.; Hanany, Shaul; Hart, Luke; Hernández-Monteagudo, C.; Hill, J. Colin; Hotinli, Selim C.; Karatsu, K.; Karkare, K. S.; Keating, Garrett K.; Khabibullin, Ildar; Kogut, A.; Kohri, Kazunori; Kovetz, Ely D.; Lagache, G.; Lesgourgues, Julien; Madhavacheril, Mathew S.; Maffei, B.; Mandolesi, N.; Martins, C. J. A. P.; Masi, S.; Mather, John C.; Melin, J.-B.; Dizgah, Azadeh Moradinezhad; Mroczkowski, Tony; Mukherjee, Suvodip; Nagai, Daisuke; Negrello, M.; Palanque-Delabrouille, N.; Paoletti, D.; Patil, Subodh P.; Raghunathan, S.; Ravenni, Andrea; Remazeilles, M.; Revéret, V.; Rodriguez, L.; Rotti, Aditya; Martín, José Alberto Rubiño; Sayers, Jack; Scott, Douglas; Silk, Joseph; Silva, Marta; Souradeep, T.; Sugiyama, Naonori S.; Sunyaev, R.; Switzer, Eric R.; Tartari, A.; Trombetti, T.; Zubeldia, Íñigo

doi:10.1007/s10686-021-09721-z

Cited by 23 publications

(21 citation statements)

References 168 publications

(175 reference statements)

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“…However, we derive general formulas that make the analysis reproducible for a specific inflationary model through the implementation of publicly available numerical codes. Our results may be relevant in sight of the CMB experiments that are going after the first detection of CMB B modes from tensor perturbations (LiteBIRD [55,56], PICO [57]) and µ-spectral distortions (PIXIE and its advanced iterations [58,59] and possible probe class mission proposals [60]).…”

Section: Introductionmentioning

confidence: 92%

Primordial tensor bispectra in $μ$-CMB cross-correlations

Orlando,

Meerburg,

Patil

2021

Preprint

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Cross-correlations between Cosmic Microwave Background (CMB) temperature and polarization anisotropies and µ-spectral distortions have been considered to measure (squeezed) primordial scalar bispectra in a range of scales inaccessible to primary CMB bispectra. In this work we address whether it is possible to constrain tensor non-Gaussianities with these cross-correlations. We find that only primordial tensor bispectra with anisotropies leave distinct signatures, while isotropic tensor bispectra leave either vanishing or highly suppressed signatures. We discuss how the kind of anisotropies and the parity state in primordial bispectra determine the non-zero cross-correlations. By employing the so-called BipoSH formalism to capture the observational effects of these anisotropies, we make Fisher-forecasts to assess the detection prospects from µT , µE and µB cross-correlations. Observing anisotropies in squeezed γγγ and γγζ bispectra is going to be challenging as the imprint of tensor perturbations on µ-distortions is subdominant to scalar perturbations, therefore requiring a large, independent amplification of the effect of tensor perturbations in the µ-epoch. In absence of such a mechanism, anisotropies in squeezed ζζγ bispectrum are the most relevant sources of µT , µE and µB cross-correlations. In particular, we point out that in models where anisotropies in ζζζ leave potentially observable signatures in µT and µE, the detection prospects of anisotropies in ζζγ from µB are enhanced.

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Section: Introductionmentioning

confidence: 92%

Primordial tensor bispectra in $μ$-CMB cross-correlations

Orlando,

Meerburg,

Patil

2021

Preprint

Self Cite

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“…This "Voyage 2050" process defined the science themes for the next three large-class (L-class, ∼ 1 billion Euro) missions, but did not yet define the specific mission concepts. A coordinated series of whitepapers proposed science themes on spectral distortions [96], on using the CMB as a backlight for mapping structures and their baryon content [97], on cosmology via probing structure evolution across cosmic times with line-intensity mapping [98], and on an L-class mission to target them all, with compromises to be made between the different science cases [99]. The Final recommendations from the Voyage 2050 Senior Committee [100] selected "New Physical Probes of the Early Universe" as one of the science themes, and recommended "a Large mission deploying gravitational wave detectors or precision microwave spectrometers to explore the early Universe at large redshifts."…”

Section: European Effortsmentioning

confidence: 99%

Snowmass2021 Cosmic Frontier: Cosmic Microwave Background Measurements White Paper

Chang,

Huffenberger,

Benson

et al. 2022

Preprint

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“…In what follows we provide forecasts for the 'direct-detection' prospects for the kpSZ effect using CMB-S4, CMB-HD and PIXIE experiments. In addition to these upcoming LiteBIRD [70,71] and proposed ESA Voyage 2050 [72,73] surveys can also potentially improve the prospects of detecting this effect directly on large scales by cross-correlating with velocity templates.…”

Section: Detecting the Signal A Ilc-cleaned Kpsz Mapsmentioning

confidence: 99%

Cosmology from the kinetic polarized Sunyaev Zel'dovich effect

Hotinli¹,

Holder²,

Johnson³

et al. 2022

Preprint

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The cosmic microwave background (CMB) photons that scatter off free electrons in the large-scale structure induce a linear polarization pattern proportional to the remote CMB temperature quadrupole observed in the electrons' rest frame. The associated blackbody polarization anisotropies are known as the polarized Sunyaev Zel'dovich (pSZ) effect. Relativistic corrections to the remote quadrupole field give rise to a non-blackbody polarization anisotropy proportional to the square of the transverse peculiar velocity field; this is the kinetic polarized Sunyaev Zel'dovich (kpSZ) effect. In this paper, we forecast the ability of future CMB and galaxy surveys to detect the kpSZ effect, finding that a statistically significant detection is within the reach of planned experiments. We further introduce a quadratic estimator for the square of the peculiar velocity field based on a galaxy survey and CMB polarization. Finally, we outline how the kpSZ effect is a probe of cosmic birefringence and primordial non-Gaussianity, forecasting the reach of future experiments.

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Microwave spectro-polarimetry of matter and radiation across space and time

Cited by 23 publications

References 168 publications

Primordial tensor bispectra in $μ$-CMB cross-correlations

Primordial tensor bispectra in $μ$-CMB cross-correlations

Snowmass2021 Cosmic Frontier: Cosmic Microwave Background Measurements White Paper

Cosmology from the kinetic polarized Sunyaev Zel'dovich effect

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