Your search keyword '"Dumoulin, R. N."' showing total 3 results

1. THE Q/U IMAGING EXPERIMENT INSTRUMENT.

Author

BISCHOFF, C., BRIZIUS, A., BUDER, I., Y. CHINONE, CLEARY, K., DUMOULIN, R. N., KUSAKA, A., MONSALVE, R., NÆSS, S. K., NEWBURGH, L. B., NIXON, G., REEVES, R., SMITH, K. M., VANDERLINDE, K., WEHUS, I. K., BOGDAN, M., BUSTOS, R., CHURCH, S. E., DAVIS, R., and DICKINSON, C.

Subjects

*COSMIC background radiation, *GRAVITATIONAL waves, *BINARY pulsars, *POLARISCOPE, *FOCAL planes, *ELECTRON mobility

Abstract

The Q/U Imaging ExperimenT (QUIET) is designed to measure polarization in the cosmic microwave background, targeting the imprint of inflationary gravitational waves at large angular scales(~1°). Between 2008 October and 2010 December, two independent receiver arrays were deployed sequentially on a 1.4m side-fed Dragonian telescope. The polarimeters that form the focal planes use a compact design based on high electron mobility transistors (HEMTs) that provides simultaneous measurements of the Stokes parameters Q, U, and I in a single module. The 17-element Q-band polarimeter array, with a central frequency of 43.1 GHz, has the best sensitivity (69 μKs½) and the lowest instrumental systematic errors ever achieved in this band, contributing to the tensor-to-scalar ratio at r < 0.1. The 84-element W-band polarimeter array has a sensitivity of 87 μKs½ at a central frequency of 94.5 GHz. It has the lowest systematic errors to date, contributing at r < 0.01. The two arrays together cover multipoles in the range l ~ 25-975. These are the largest HEMT-based arrays deployed to date. This article describes the design, calibration, performance, and sources of systematic error of the instrument. [ABSTRACT FROM AUTHOR]

Published

2013

2. FIRST SEASON QUIET OBSERVATIONS: MEASUREMENTS OF COSMIC MICROWAVE BACKGROUND POLARIZATION POWER SPECTRA AT 43 GHz IN THE MULTIPOLE RANGE 25 ≤ ℓ ≤ 475.

Author

BISCHOFF, C., BRIZIUS, A., BUDER, I., CHINONE, Y., CLEARY, K., DUMOULIN, R. N., KUSAKA, A., MONSALVE, R., NÆSS, S. K., NEWBURGH, L. B., REEVES, R., SMITH, K. M., WEHUS, I. K., ZUNTZ, J. A., ZWART, J. T. L., BRONFMAN, L., BUSTOS, R., CHURCH, S. E., DICKINSON, C., and ERIKSEN, H. K.

Subjects

*COSMIC background radiation, *MEASUREMENT, *OPTICAL polarization, *ANISOTROPY, *SYNCHROTRON radiation

Abstract

The Q/U Imaging ExperimenT (QUIET) employs coherent receivers at 43 GHz and 94 GHz, operating on the Chajnantor plateau in the Atacama Desert in Chile, to measure the anisotropy in the polarization of the cosmic microwave background (CMB). QUIET primarily targets the B modes from primordial gravitational waves. The combination of these frequencies gives sensitivity to foreground contributions from diffuse Galactic synchrotron radiation. Between 2008 October and 2010 December, over 10,000 hr of data were collected, first with the 19 element 43 GHz array (3458 hr) and then with the 90 element 94 GHz array. Each array observes the same four fields, selected for low foregrounds, together covering %1000 deg². This paper reports initial results from the 43 GHz receiver, which has an array sensitivity to CMB fluctuations of 69 µK√s. The data were extensively studied with a large suite of null tests before the power spectra, determined with two independent pipelines, were examined. Analysis choices, including data selection, were modified until the null tests passed. Cross-correlating maps with different telescope pointings is used to eliminate a bias. This paper reports the EE, BB, and EB power spectra in the multipole range ℓ = 25-475. With the exception of the lowest multipole bin for one of the fields, where a polarized foreground, consistent with Galactic synchrotron radiation, is detected with 3cr significance, the E-mode spectrum is consistent with the ACDM model, confirming the only previous detection of the first acoustic peak. The B-mode spectrum is consistent with zero, leading to a measurement of the tensor-to-scalar ratio of Due to image rights restrictions, multiple line equation(s) cannot be graphically displayed. The combination of a new time-stream "double-demodulation" technique, side-fed Dragoman optics, natural sky rotation, and frequent boresight rotation leads to the lowest level of systematic contamination in the B-mode power so far reported, below the level of r = 0.1. [ABSTRACT FROM AUTHOR]

Published

2011

3. SECOND SEASON QUIET OBSERVATIONS: MEASUREMENTS OF THE COSMIC MICROWAVE BACKGROUND POLARIZATION POWER SPECTRUM AT 95 GHz.

Author

Collaboration, QUIET, Araujo, D., Bischoff, C., Brizius, A., Buder, I., Chinone, Y., Cleary, K., Dumoulin, R. N., Kusaka, A., Monsalve, R., Næss, S. K., Newburgh, L. B., Reeves, R., Wehus, I. K., Zwart, J. T. L., Bronfman, L., Bustos, R., Church, S. E., Dickinson, C., and Eriksen, H. K.

Subjects

*COSMIC background radiation, *POLARIZATION (Nuclear physics), *ASTROPHYSICAL radiation, *GRAVITATIONAL waves, *GRAVITATIONAL wave astronomy

Abstract

The Q/U Imaging ExperimenT (QUIET) has observed the cosmic microwave background (CMB) at 43 and 95 GHz. The 43 GHz results have been published in a previous paper, and here we report the measurement of CMB polarization power spectra using the 95 GHz data. This data set comprises 5337 hr of observations recorded by an array of 84 polarized coherent receivers with a total array sensitivity of 87 μK. Four low-foreground fields were observed, covering a total of ∼1000 deg2 with an effective angular resolution of 12.′8, allowing for constraints on primordial gravitational waves and high signal-to-noise measurements of the E-modes across three acoustic peaks. The data reduction was performed using two independent analysis pipelines, one based on a pseudo-Cℓ (PCL) cross-correlation approach, and the other on a maximum-likelihood (ML) approach. All data selection criteria and filters were modified until a predefined set of null tests had been satisfied before inspecting any non-null power spectrum. The results derived by the two pipelines are in good agreement. We characterize the EE, EB, and BB power spectra between ℓ = 25 and 975 and find that the EE spectrum is consistent with ΛCDM, while the BB power spectrum is consistent with zero. Based on these measurements, we constrain the tensor-to-scalar ratio to r = 1.1+0.9– 0.8 (r < 2.8 at 95% C.L.) as derived by the ML pipeline, and r = 1.2+0.9– 0.8 (r < 2.7 at 95% C.L.) as derived by the PCL pipeline. In one of the fields, we find a correlation with the dust component of the Planck Sky Model, though the corresponding excess power is small compared to statistical errors. Finally, we derive limits on all known systematic errors, and demonstrate that these correspond to a tensor-to-scalar ratio smaller than r = 0.01, the lowest level yet reported in the literature. [ABSTRACT FROM AUTHOR]

Published

2012