QUBIC I: Overview and science program

Hamilton, Jean-Christophe; Mousset, L.; Battistelli, E. S.; Bernardis, P. de; Bigot-Sazy, M.-A.; Chanial, P.; Charlassier, R.; D’Alessandro, G.; Petris, M. De; Lerena, M.M. Gamboa; Grandsire, L.; Landau, Susana J.; Mandelli, S.; Marnieros, S.; Masi, S.; Mennella, A.; O'Sullivan, Créidhe M.; Piat, M.; Ricciardi, Giulia; Scóccola, Claudia G.; Stolpovskiy, M.; Tartari, A.; Torchinsky, S.; Voisin, F.; Zannoni, M.; Ade, Peter A. R.; Alberro, J.G.; Almela, A.; Amico, G.; Arnaldi, L. H.; Auguste, Didier; Aumont, J.; Azzoni, S.; Banfi, Stefano; Baù, A.; Bélier, B.; Bennett, D.; Bergé, L.; Bernard, J.-P.; Bersanelli, M.; Bonaparte, J.; Bonis, J.; Bunn, Emory F.; Burke, David; Buzi, D.; Cavaliere, F.; Chapron, C.; Cerutti, Agustín Cobos; Columbro, F.; Coppolecchia, A.; Gasperis, G. de; Leo, M. De; Dheilly, S.; Duca, C.; Dumoulin, L.; Etchegoyen, A.; Fasciszewski, A.; Ferreyro, L.P.; Fracchia, D.; Franceschet, C.; Ganga, K.; García, Beatriz; Redondo, M.E. García; Gaspard, M.; Gayer, D.; Gervasi, M.; Giard, M.; Gilles, V.; Giraud‐Héraud, Y.; Berisso, M. Gómez; González, M.; Grądziel, M.; Hampel, Matías Rolf; Harari, D.; Henrot-Versillé, S.; Incardona, F.; Jules, E.; Kaplan, J.; Kristukat, C.; Lamagna, L.; Loucatos, S.; Louis, Thibaut; Maffei, B.; Marty, W.; Mattei, A.; May, A.; McCulloch, M.; Mele, L.; Melo, D.; Montier, L.; Mundo, L.M.; Murphy, J. Anthony; Murphy, J.D.; Nati, F.; Olivieri, E.; Oriol, C.; Paiella, A.; Pajot, F.; Passerini, A.; Pastoriza, H.; Pelosi, A.; Perbost, C.; Perciballi, M.; Pezzotta, F.; Piacentini, F.; Piccirillo, L.; Pisano, G.; Platino, M.; Polenta, G.; Prêle, D.; Puddu, Roberto; Rambaud, D.; Rasztocky, E.; Ringegni, P.; Romero, Gustavo E.; Salum, J.M.; Schillaci, A.; Scully, Stephen; Spinelli, S.; Stankowiak, G.; Supanitsky, A. D.; Thermeau, Jean‐Pierre; Timbie, Peter; Tomasi, M.; Tucker, C.; Tucker, Gregory S.; Viganò, Daniele; Vittorio, N.; Wicek, F.; Wright, M.; Zullo, A.

doi:10.1088/1475-7516/2022/04/034

Cited by 27 publications

(41 citation statements)

References 85 publications

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“…To this end, both on-going and future groundbased [58][59][60][61][62][63][64][65][66], balloon-borne [67,68], and spaceborne [69,70] experiments are expected to lead to a convincing discovery (or otherwise) of cosmic birefringence. If proven to be a cosmological signal, isotropic cosmic birefringence would have a profound impact on cosmology, particle physics, and quantum gravity [71][72][73][74][75][76][77][78][79][80][81].…”

Section: Discussionmentioning

confidence: 99%

Improved Constraints on Cosmic Birefringence from the WMAP and Planck Cosmic Microwave Background Polarization Data

Eskilt,

Komatsu

2022

Preprint

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The observed pattern of linear polarization of the cosmic microwave background (CMB) photons is a sensitive probe of physics violating parity symmetry under inversion of spatial coordinates. A new parity-violating interaction might have rotated the plane of linear polarization by an angle β as the CMB photons have been traveling for more than 13 billion years. This effect is known as "cosmic birefringence." In this paper, we present new measurements of cosmic birefringence from a joint analysis of polarization data from two space missions, Planck and WMAP. This dataset covers a wide range of frequencies from 23 to 353 GHz. We measure β = 0.342 • +0.094 • −0.091 • (68% C.L.) for nearly full-sky data, which excludes β = 0 at 99.987% C.L. This corresponds to the statistical significance of 3.6σ. There is no evidence for frequency dependence of β. We find a similar result, albeit with a larger uncertainty, when removing the Galactic plane from the analysis.

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Section: Discussionmentioning

confidence: 99%

Improved Constraints on Cosmic Birefringence from the WMAP and Planck Cosmic Microwave Background Polarization Data

Eskilt,

Komatsu

2022

Preprint

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“…We can see that the Galactic dust is efficiently reconstructed in the 5 sub-bands as the residuals are compatible with pure noise. Note that the noise is not white but has spatial correlations due to the deconvolution with the multi-peak synthesized beam (see section 3.1.1 in Hamilton et al [24]). We also note that the residuals are higher on the edges than in the center of the sky patch.…”

Section: Galactic Dustmentioning

confidence: 99%

“…In section 5.1 it was shown that a polychromatic interferometer has anti-correlations in neighbouring bands for each Stokes parameter. Furthermore, the spatial structure of noise is studied in detail in Hamilton et al [24] using end-to-end simulations. This allows us to build a fast noise simulator that reproduces efficiently the noise behaviour in the reconstructed maps.…”

Section: Noise Analysis Using the Power Spectrummentioning

confidence: 99%

“…The synthesized beam contains multiple peaks whose angular separation is linearly dependent on the wavelength. This paper does not attempt to make realistic simulations and forecasts for the QUBIC project, this is addressed in the companion paper Hamilton et al [24]. The goal is to demonstrate spectral imaging technique on simple cases, with very basic foreground models, not accounting for any systematic effect.…”

Section: Introductionmentioning

confidence: 99%

“…Detailed information about QUBIC can be found in the companion papers: scientific overview and expected performance of QUBIC [24], characterization of the technological demonstrator (TD) [25], transition-edge sensors and readout characterization [26], cryogenic system performance [27], half-wave plate (HWP) rotator design and performance [28 1. QUBIC main parameters (from Hamilton et al [24]) horn-switches system of the TD [29], and optical design and performance [30].…”

Section: Introductionmentioning

confidence: 99%

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QUBIC II: Spectral polarimetry with bolometric interferometry

Mousset¹,

Lerena²,

Battistelli³

et al. 2022

J. Cosmol. Astropart. Phys.

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Bolometric interferometry is a novel technique that has the ability to perform spectral imaging. A bolometric interferometer observes the sky in a wide frequency band and can reconstruct sky maps in several sub-bands within the physical band in post-processing of the data. This provides a powerful spectral method to discriminate between the cosmic microwave background (CMB) and astrophysical foregrounds. In this paper, the methodology is illustrated with examples based on the Q & U Bolometric Interferometer for Cosmology (QUBIC) which is a ground-based instrument designed to measure the B-mode polarization of the sky at millimeter wavelengths. We consider the specific cases of point source reconstruction and Galactic dust mapping and we characterize the point spread function as a function of frequency. We study the noise properties of spectral imaging, especially the correlations between sub-bands, using end-to-end simulations together with a fast noise simulator. We conclude showing that spectral imaging performance are nearly optimal up to five sub-bands in the case of QUBIC.

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Polarization Modulator Unit Harness Thermal Design for the Mid- and High-Frequency Telescopes of the LiteBIRD Space Mission

2022

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Polarization modulator units (PMUs) represent a critical and powerful component in CMB polarization experiments to suppress the 1/f noise component and mitigate systematic uncertainties induced by detector gain drifts and beam asymmetries. The LiteBIRD mission (expected launch in the late 2020 s) will be equipped with 3 PMUs, one for each of the 3 telescopes, and aims at detecting the primordial gravitational waves with a sensitivity of $$\delta r<0.001$$ δ r < 0.001 . Each PMU is based on a continuously rotating transmissive half-wave plate held by a superconducting magnetic bearing in the 5 K environment. To achieve and monitor the rotation a number of subsystems is needed: clamp and release system and motor coils for the rotation; optical encoder, capacitive, Hall and temperature sensors to monitor its dynamic stability. In this contribution, we present a preliminary thermal design of the harness configuration for the PMUs of the mid- and high- frequency telescopes. The design is based on both the stringent system constraint for the total thermal budget available for the PMUs ($$\lesssim$$ ≲ 4 mW at 5 K) and on the requirements for different subsystem: coils currents (up to 10 mA), optical fibers for encoder readout, 25 MHz bias signal for temperature and levitation monitors.

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QUBIC I: Overview and science program

Cited by 27 publications

References 85 publications

Improved Constraints on Cosmic Birefringence from the WMAP and Planck Cosmic Microwave Background Polarization Data

Improved Constraints on Cosmic Birefringence from the WMAP and Planck Cosmic Microwave Background Polarization Data

QUBIC II: Spectral polarimetry with bolometric interferometry

Polarization Modulator Unit Harness Thermal Design for the Mid- and High-Frequency Telescopes of the LiteBIRD Space Mission

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