Your search keyword '"O'Dea, D."' showing total 32 results

1. Overview of Liquid-Metal PFC R&D at the University of Illinois Urbana-Champaign

Author

Andruczyk, D., Rizkallah, R., O’Dea, D., Shone, A., Smith, S., Kamiyama, B., Maingi, R., Kessel, C.E., Smolentsev, S., Morgan, T.W., Romano, F., Andruczyk, D., Rizkallah, R., O’Dea, D., Shone, A., Smith, S., Kamiyama, B., Maingi, R., Kessel, C.E., Smolentsev, S., Morgan, T.W., and Romano, F.

Abstract

The design and implementation of future flowing liquid-lithium plasma-facing components (LLPFCs) will be dependent on several factors. Of course, one of the most important is the need to be able to deal with high heat fluxes incident on the surface of the LLPFCs, but there are also several other important liquid-metal behaviors that have been identified for their critical impact on the feasibility of a LLPFC. One of these is the ability to constantly wet 100% of the plasma-facing component area and the best way to achieve that. Another key point is knowing and understanding the erosion and corrosion of the surfaces subject to a flowing liquid-lithium system and the ability for hydrogen and helium uptake by the system. The Center for Plasma Material Interactions (CPMI) has been tasked with looking at these various issues. The Mock-up Entry module for EAST device was used to investigate wetting and erosion effects and to design a suitable distribution and collection system with a liquid-lithium loop. The vapor shielding effects of lithium on the surface were also modeled and studied. A model coupling CRANE, an open-source global reaction network solver, and Zapdos, a plasma transport solver, is being developed to better understand the dynamics of the vapor cloud. Experiments on the Magnum-PSI at the Dutch Institute for Fundamental Energy Research have been carried out to study the vapor shielding effect and obtain experimental benchmarks to verify the model. Also, initial experiments using the Hybrid Illinois Device for Research and Applications have been performed to understand the pumping effects of lithium on helium. Experiments with a drop of liquid lithium (~100 mg) into a helium plasma have shown the ability of lithium to take out the cold recycling helium gas as well as hydrogen and oxygen impurity gases. The improvement in plasma performance was significant, and further understanding of this effect will have impacts on how future LLPFCs will be designed. Fu

Published

2023

2. Targeting CDK4 and 6 in Cancer Therapy: Emerging Preclinical Insights Related to Abemaciclib

Author

Wander, SA, O'Brien, N, Litchfield, LM, O'Dea, D, Guimaraes, CM, Slamon, DJ, Goel, S, Wander, SA, O'Brien, N, Litchfield, LM, O'Dea, D, Guimaraes, CM, Slamon, DJ, and Goel, S

Abstract

Pharmacologic inhibitors of cyclin-dependent kinases 4 and 6 (CDK4 and 6) are approved for the treatment of subsets of patients with hormone receptor positive (HR+) breast cancer (BC). In metastatic disease, strategies involving endocrine therapy combined with CDK4 and 6 inhibitors (CDK4 and 6i) improve clinical outcomes in HR+ BCs. CDK4 and 6i prevent retinoblastoma tumor suppressor protein phosphorylation, thereby blocking the transcription of E2F target genes, which in turn inhibits both mitogen and estrogen-mediated cell proliferation. In this review, we summarize preclinical data pertaining to the use of CDK4 and 6i in BC, with a particular focus on several of the unique chemical, pharmacologic, and mechanistic properties of abemaciclib. As research efforts elucidate the novel mechanisms underlying abemaciclib activity, potential new applications are being identified. For example, preclinical studies have demonstrated abemaciclib can exert antitumor activity against multiple tumor types and can cross the blood-brain barrier. Abemaciclib has also demonstrated distinct activity as a monotherapeutic in the treatment of BC. Accordingly, we also discuss how a greater understanding of mechanisms related to CDK4 and 6 blockade highlight abemaciclib's unique in-class properties, and could pave new avenues for enhancing its therapeutic efficacy.

Published

2022

3. The Impact of the Spectral Response of an Achromatic Half-Wave Plate on the Measurement of the Cosmic Microwave Background Polarization

Author

Bao, C., Gold, B., Baccigalupi, C., Didier, J., Hanany, S., Jaffe, A., Johnson, B. R., Leach, S., Matsumura, T., Miller, A., O'Dea, D., Bao, C., Gold, B., Baccigalupi, C., Didier, J., Hanany, S., Jaffe, A., Johnson, B. R., Leach, S., Matsumura, T., Miller, A., and O'Dea, D.

Abstract

We study the impact of the spectral dependence of the linear polarization rotation induced by an achromatic half-wave plate on measurements of cosmic microwave background polarization in the presence of astrophysical foregrounds. We focus on the systematic effects induced on the measurement of inflationary gravitational waves by uncertainties in the polarization and spectral index of Galactic dust. We find that for the experimental configuration and noise levels of the balloon-borne EBEX experiment, which has three frequency bands centered at 150, 250, and 410 GHz, a crude dust subtraction process mitigates systematic effects to below detectable levels for 10% polarized dust and tensor to scalar ratio of as low as r = 0.01. We also study the impact of uncertainties in the spectral response of the instrument. With a top-hat model of the spectral response for each band, characterized by band-center and band-width, and with the same crude dust subtraction process, we find that these parameters need to be determined to within 1 and 0.8 GHz at 150 GHz; 9 and 2.0 GHz at 250 GHz; and 20 and 14 GHz at 410 GHz, respectively. The approach presented in this paper is applicable to other optical elements that exhibit polarization rotation as a function of frequency., Comment: 6 pages, 7 figures, accepted for publication by Astrophysical Journal

Published

2011

4. Ultra High Energy Cosmology with POLARBEAR

Author

Keating, B., Moyerman, S., Boettger, D., Edwards, J., Fuller, G., Matsuda, F., Miller, N., Paar, H., Rebeiz, G., Schanning, I., Shimon, M., Stebor, N., Arnold, K., Flanigan, D., Holzapfel, W., Howard, J., Kermish, Z., Lee, A., Lungu, M., Myers, M., Nishino, H., O'Brient, R., Quealy, E., Reichardt, C., Richards, P., Shimmin, C., Steinbach, B., Suzuki, A., Zahn, O., Borrill, J., Cantalupo, C., Kisner, E., Linder, E., Sholl, M., Spieler, H., Anthony, A., Halverson, N., Errard, J., Fabbian, G., Jeune, M. Le, Stompor, R., Jaffe, A., O'Dea, D., Chinone, Y., Hasegawa, M., Hazumi, M., Matsumura, T., Morii, H., Shimizu, A., Tomaru, T., Hyland, P., Dobbs, M., Ade, P., Grainger, W., Tucker, C., Keating, B., Moyerman, S., Boettger, D., Edwards, J., Fuller, G., Matsuda, F., Miller, N., Paar, H., Rebeiz, G., Schanning, I., Shimon, M., Stebor, N., Arnold, K., Flanigan, D., Holzapfel, W., Howard, J., Kermish, Z., Lee, A., Lungu, M., Myers, M., Nishino, H., O'Brient, R., Quealy, E., Reichardt, C., Richards, P., Shimmin, C., Steinbach, B., Suzuki, A., Zahn, O., Borrill, J., Cantalupo, C., Kisner, E., Linder, E., Sholl, M., Spieler, H., Anthony, A., Halverson, N., Errard, J., Fabbian, G., Jeune, M. Le, Stompor, R., Jaffe, A., O'Dea, D., Chinone, Y., Hasegawa, M., Hazumi, M., Matsumura, T., Morii, H., Shimizu, A., Tomaru, T., Hyland, P., Dobbs, M., Ade, P., Grainger, W., and Tucker, C.

Abstract

Observations of the temperature anisotropy of the Cosmic Microwave Background (CMB) lend support to an inflationary origin of the universe, yet no direct evidence verifying inflation exists. Many current experiments are focussing on the CMB's polarization anisotropy, specifically its curl component (called "B-mode" polarization), which remains undetected. The inflationary paradigm predicts the existence of a primordial gravitational wave background that imprints a unique B-mode signature on the CMB's polarization at large angular scales. The CMB B-mode signal also encodes gravitational lensing information at smaller angular scales, bearing the imprint of cosmological large scale structures (LSS) which in turn may elucidate the properties of cosmological neutrinos. The quest for detection of these signals; each of which is orders of magnitude smaller than the CMB temperature anisotropy signal, has motivated the development of background-limited detectors with precise control of systematic effects. The POLARBEAR experiment is designed to perform a deep search for the signature of gravitational waves from inflation and to characterize lensing of the CMB by LSS. POLARBEAR is a 3.5 meter ground-based telescope with 3.8 arcminute angular resolution at 150 GHz. At the heart of the POLARBEAR receiver is an array featuring 1274 antenna-coupled superconducting transition edge sensor (TES) bolometers cooled to 0.25 Kelvin. POLARBEAR is designed to reach a tensor-to-scalar ratio of 0.025 after two years of observation -- more than an order of magnitude improvement over the current best results, which would test physics at energies near the GUT scale. POLARBEAR had an engineering run in the Inyo Mountains of Eastern California in 2010 and will begin observations in the Atacama Desert in Chile in 2011., Comment: 8 pages, 6 figures, DPF 2011 conference proceedings

Published

2011

5. A Model For Polarised Microwave Foreground Emission From Interstellar Dust

Author

O'Dea, D. T., Clark, C. N., Contaldi, C. R., MacTavish, C. J., O'Dea, D. T., Clark, C. N., Contaldi, C. R., and MacTavish, C. J.

Abstract

The upcoming generation of cosmic microwave background (CMB) experiments face a major challenge in detecting the weak cosmic B-mode signature predicted as a product of primordial gravitational waves. To achieve the required sensitivity these experiments must have impressive control of systematic effects and detailed understanding of the foreground emission that will influence the signal. In this paper, we present templates of the intensity and polarisation of emission from one of the main Galactic foregrounds, interstellar dust. These are produced using a model which includes a 3D description of the Galactic magnetic field, examining both large and small scales. We also include in the model the details of the dust density, grain alignment and the intrinsic polarisation of the emission from an individual grain. We present here Stokes parameter template maps at 150GHz and provide an on-line repository (http://www.imperial.ac.uk/people/c.contaldi/fgpol) for these and additional maps at frequencies that will be targeted by upcoming experiments such as EBEX, Spider and SPTpol., Comment: 7 pages, 4 figures

Published

2011

6. SPIDER: Probing the Early Universe with a Suborbital Polarimeter

Author

Fraisse, A. A., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Doré, O., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Wiebe, D., Fraisse, A. A., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Doré, O., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., and Wiebe, D.

Abstract

We evaluate the ability of SPIDER, a balloon-borne polarimeter, to detect a divergence-free polarization pattern ("B-modes") in the Cosmic Microwave Background (CMB). In the inflationary scenario, the amplitude of this signal is proportional to that of the primordial scalar perturbations through the tensor-to-scalar ratio r. We show that the expected level of systematic error in the SPIDER instrument is significantly below the amplitude of an interesting cosmological signal with r=0.03. We present a scanning strategy that enables us to minimize uncertainty in the reconstruction of the Stokes parameters used to characterize the CMB, while accessing a relatively wide range of angular scales. Evaluating the amplitude of the polarized Galactic emission in the SPIDER field, we conclude that the polarized emission from interstellar dust is as bright or brighter than the cosmological signal at all SPIDER frequencies (90 GHz, 150 GHz, and 280 GHz), a situation similar to that found in the "Southern Hole." We show that two ~20-day flights of the SPIDER instrument can constrain the amplitude of the B-mode signal to r<0.03 (99% CL) even when foreground contamination is taken into account. In the absence of foregrounds, the same limit can be reached after one 20-day flight., Comment: 29 pages, 8 figures, 4 tables; v2: matches published version, flight schedule updated, two typos fixed in Table 2, references and minor clarifications added, results unchanged

Published

2011

7. Thermal architecture for the SPIDER flight cryostat

Author

Gudmundsson, J. E., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Halpern, M., Hasselfield, M., Helson, K. R., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Gudmundsson, J. E., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Halpern, M., Hasselfield, M., Helson, K. R., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., and Turner, A. D.

Abstract

We describe the cryogenic system for SPIDER, a balloon-borne microwave polarimeter that will map 8% of the sky with degree-scale angular resolution. The system consists of a 1284 L liquid helium cryostat and a 16 L capillary-filled superfluid helium tank, which provide base operating temperatures of 4 K and 1.5 K, respectively. Closed-cycle helium-3 adsorption refrigerators supply sub-Kelvin cooling power to multiple focal planes, which are housed in monochromatic telescope inserts. The main helium tank is suspended inside the vacuum vessel with thermally insulating fiberglass flexures, and shielded from thermal radiation by a combination of two vapor cooled shields and multi-layer insulation. This system allows for an extremely low instrumental background and a hold time in excess of 25 days. The total mass of the cryogenic system, including cryogens, is approximately 1000 kg. This enables conventional long duration balloon flights. We will discuss the design, thermal analysis, and qualification of the cryogenic system., Comment: 11 pages, 4 figures; as published in the conference proceedings for SPIE Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy V (2010)

Published

2011

8. Design and performance of the Spider instrument

Author

Runyan, M. C., Ade, P. A. R., Amiri, M., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L., Gandilo, N., Golwala, S. R., Gudmundsson, J. E., Hasselfield, M., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Morford, T. A., Montroy, T. E., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Schenker, M. A., Shariff, J., Soler, J. D., Trangsrud, A., Tucker, R. S., Tucker, C., Turner, A., Runyan, M. C., Ade, P. A. R., Amiri, M., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L., Gandilo, N., Golwala, S. R., Gudmundsson, J. E., Hasselfield, M., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Morford, T. A., Montroy, T. E., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Schenker, M. A., Shariff, J., Soler, J. D., Trangsrud, A., Tucker, R. S., Tucker, C., and Turner, A.

Abstract

Here we describe the design and performance of the Spider instrument. Spider is a balloon-borne cosmic microwave background polarization imager that will map part of the sky at 90, 145, and 280 GHz with sub-degree resolution and high sensitivity. This paper discusses the general design principles of the instrument inserts, mechanical structures, optics, focal plane architecture, thermal architecture, and magnetic shielding of the TES sensors and SQUID multiplexer. We also describe the optical, noise, and magnetic shielding performance of the 145 GHz prototype instrument insert., Comment: 12 pages, 5 figures, Proceedings of SPIE, Astronomical Telescopes and Instrumentation 2010, San Diego, CA

Published

2011

9. SPIDER: a balloon-borne CMB polarimeter for large angular scales

Author

Filippini, J. P., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Doré, O., Farhang, M., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Gudmundsson, J. E., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Filippini, J. P., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Doré, O., Farhang, M., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Gudmundsson, J. E., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., and Turner, A. D.

Abstract

We describe SPIDER, a balloon-borne instrument to map the polarization of the millimeter-wave sky with degree angular resolution. Spider consists of six monochromatic refracting telescopes, each illuminating a focal plane of large-format antenna-coupled bolometer arrays. A total of 2,624 superconducting transition-edge sensors are distributed among three observing bands centered at 90, 150, and 280 GHz. A cold half-wave plate at the aperture of each telescope modulates the polarization of incoming light to control systematics. Spider's first flight will be a 20-30-day Antarctic balloon campaign in December 2011. This flight will map \sim8% of the sky to achieve unprecedented sensitivity to the polarization signature of the gravitational wave background predicted by inflationary cosmology. The Spider mission will also serve as a proving ground for these detector technologies in preparation for a future satellite mission., Comment: 12 pages, 6 figures; as published in the conference proceedings for SPIE Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy V (2010)

Published

2011

10. Spider Optimization II: Optical, Magnetic and Foreground Effects

Author

O'Dea, D. T., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Dore, O., Farhang, M., Filippini, J. P., Fissel, L. M., Fraisse, A. A., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Wiebe, D., O'Dea, D. T., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Dore, O., Farhang, M., Filippini, J. P., Fissel, L. M., Fraisse, A. A., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., and Wiebe, D.

Abstract

Spider is a balloon-borne instrument designed to map the polarization of the cosmic microwave background (CMB) with degree-scale resolution over a large fraction of the sky. Spider's main goal is to measure the amplitude of primordial gravitational waves through their imprint on the polarization of the CMB if the tensor-to-scalar ratio, r, is greater than 0.03. To achieve this goal, instrumental systematic errors must be controlled with unprecedented accuracy. Here, we build on previous work to use simulations of Spider observations to examine the impact of several systematic effects that have been characterized through testing and modeling of various instrument components. In particular, we investigate the impact of the non-ideal spectral response of the half-wave plates, coupling between focal plane components and the Earth's magnetic field, and beam mismatches and asymmetries. We also present a model of diffuse polarized foreground emission based on a three-dimensional model of the Galactic magnetic field and dust, and study the interaction of this foreground emission with our observation strategy and instrumental effects. We find that the expected level of foreground and systematic contamination is sufficiently low for Spider to achieve its science goals., Comment: submitted to APJ, 15 pages, 12 figures

Published

2011

11. The Impact of the Spectral Response of an Achromatic Half-Wave Plate on the Measurement of the Cosmic Microwave Background Polarization

Author

Bao, C., Gold, B., Baccigalupi, C., Didier, J., Hanany, S., Jaffe, A., Johnson, B. R., Leach, S., Matsumura, T., Miller, A., O'Dea, D., Bao, C., Gold, B., Baccigalupi, C., Didier, J., Hanany, S., Jaffe, A., Johnson, B. R., Leach, S., Matsumura, T., Miller, A., and O'Dea, D.

Abstract

We study the impact of the spectral dependence of the linear polarization rotation induced by an achromatic half-wave plate on measurements of cosmic microwave background polarization in the presence of astrophysical foregrounds. We focus on the systematic effects induced on the measurement of inflationary gravitational waves by uncertainties in the polarization and spectral index of Galactic dust. We find that for the experimental configuration and noise levels of the balloon-borne EBEX experiment, which has three frequency bands centered at 150, 250, and 410 GHz, a crude dust subtraction process mitigates systematic effects to below detectable levels for 10% polarized dust and tensor to scalar ratio of as low as r = 0.01. We also study the impact of uncertainties in the spectral response of the instrument. With a top-hat model of the spectral response for each band, characterized by band-center and band-width, and with the same crude dust subtraction process, we find that these parameters need to be determined to within 1 and 0.8 GHz at 150 GHz; 9 and 2.0 GHz at 250 GHz; and 20 and 14 GHz at 410 GHz, respectively. The approach presented in this paper is applicable to other optical elements that exhibit polarization rotation as a function of frequency., Comment: 6 pages, 7 figures, accepted for publication by Astrophysical Journal

Published

2011

12. Ultra High Energy Cosmology with POLARBEAR

Author

Keating, B., Moyerman, S., Boettger, D., Edwards, J., Fuller, G., Matsuda, F., Miller, N., Paar, H., Rebeiz, G., Schanning, I., Shimon, M., Stebor, N., Arnold, K., Flanigan, D., Holzapfel, W., Howard, J., Kermish, Z., Lee, A., Lungu, M., Myers, M., Nishino, H., O'Brient, R., Quealy, E., Reichardt, C., Richards, P., Shimmin, C., Steinbach, B., Suzuki, A., Zahn, O., Borrill, J., Cantalupo, C., Kisner, E., Linder, E., Sholl, M., Spieler, H., Anthony, A., Halverson, N., Errard, J., Fabbian, G., Jeune, M. Le, Stompor, R., Jaffe, A., O'Dea, D., Chinone, Y., Hasegawa, M., Hazumi, M., Matsumura, T., Morii, H., Shimizu, A., Tomaru, T., Hyland, P., Dobbs, M., Ade, P., Grainger, W., Tucker, C., Keating, B., Moyerman, S., Boettger, D., Edwards, J., Fuller, G., Matsuda, F., Miller, N., Paar, H., Rebeiz, G., Schanning, I., Shimon, M., Stebor, N., Arnold, K., Flanigan, D., Holzapfel, W., Howard, J., Kermish, Z., Lee, A., Lungu, M., Myers, M., Nishino, H., O'Brient, R., Quealy, E., Reichardt, C., Richards, P., Shimmin, C., Steinbach, B., Suzuki, A., Zahn, O., Borrill, J., Cantalupo, C., Kisner, E., Linder, E., Sholl, M., Spieler, H., Anthony, A., Halverson, N., Errard, J., Fabbian, G., Jeune, M. Le, Stompor, R., Jaffe, A., O'Dea, D., Chinone, Y., Hasegawa, M., Hazumi, M., Matsumura, T., Morii, H., Shimizu, A., Tomaru, T., Hyland, P., Dobbs, M., Ade, P., Grainger, W., and Tucker, C.

Abstract

Observations of the temperature anisotropy of the Cosmic Microwave Background (CMB) lend support to an inflationary origin of the universe, yet no direct evidence verifying inflation exists. Many current experiments are focussing on the CMB's polarization anisotropy, specifically its curl component (called "B-mode" polarization), which remains undetected. The inflationary paradigm predicts the existence of a primordial gravitational wave background that imprints a unique B-mode signature on the CMB's polarization at large angular scales. The CMB B-mode signal also encodes gravitational lensing information at smaller angular scales, bearing the imprint of cosmological large scale structures (LSS) which in turn may elucidate the properties of cosmological neutrinos. The quest for detection of these signals; each of which is orders of magnitude smaller than the CMB temperature anisotropy signal, has motivated the development of background-limited detectors with precise control of systematic effects. The POLARBEAR experiment is designed to perform a deep search for the signature of gravitational waves from inflation and to characterize lensing of the CMB by LSS. POLARBEAR is a 3.5 meter ground-based telescope with 3.8 arcminute angular resolution at 150 GHz. At the heart of the POLARBEAR receiver is an array featuring 1274 antenna-coupled superconducting transition edge sensor (TES) bolometers cooled to 0.25 Kelvin. POLARBEAR is designed to reach a tensor-to-scalar ratio of 0.025 after two years of observation -- more than an order of magnitude improvement over the current best results, which would test physics at energies near the GUT scale. POLARBEAR had an engineering run in the Inyo Mountains of Eastern California in 2010 and will begin observations in the Atacama Desert in Chile in 2011., Comment: 8 pages, 6 figures, DPF 2011 conference proceedings

Published

2011

13. A Model For Polarised Microwave Foreground Emission From Interstellar Dust

Author

O'Dea, D. T., Clark, C. N., Contaldi, C. R., MacTavish, C. J., O'Dea, D. T., Clark, C. N., Contaldi, C. R., and MacTavish, C. J.

Abstract

The upcoming generation of cosmic microwave background (CMB) experiments face a major challenge in detecting the weak cosmic B-mode signature predicted as a product of primordial gravitational waves. To achieve the required sensitivity these experiments must have impressive control of systematic effects and detailed understanding of the foreground emission that will influence the signal. In this paper, we present templates of the intensity and polarisation of emission from one of the main Galactic foregrounds, interstellar dust. These are produced using a model which includes a 3D description of the Galactic magnetic field, examining both large and small scales. We also include in the model the details of the dust density, grain alignment and the intrinsic polarisation of the emission from an individual grain. We present here Stokes parameter template maps at 150GHz and provide an on-line repository (http://www.imperial.ac.uk/people/c.contaldi/fgpol) for these and additional maps at frequencies that will be targeted by upcoming experiments such as EBEX, Spider and SPTpol., Comment: 7 pages, 4 figures

Published

2011

14. SPIDER: Probing the Early Universe with a Suborbital Polarimeter

Author

Fraisse, A. A., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Doré, O., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Wiebe, D., Fraisse, A. A., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Doré, O., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., and Wiebe, D.

Abstract

We evaluate the ability of SPIDER, a balloon-borne polarimeter, to detect a divergence-free polarization pattern ("B-modes") in the Cosmic Microwave Background (CMB). In the inflationary scenario, the amplitude of this signal is proportional to that of the primordial scalar perturbations through the tensor-to-scalar ratio r. We show that the expected level of systematic error in the SPIDER instrument is significantly below the amplitude of an interesting cosmological signal with r=0.03. We present a scanning strategy that enables us to minimize uncertainty in the reconstruction of the Stokes parameters used to characterize the CMB, while accessing a relatively wide range of angular scales. Evaluating the amplitude of the polarized Galactic emission in the SPIDER field, we conclude that the polarized emission from interstellar dust is as bright or brighter than the cosmological signal at all SPIDER frequencies (90 GHz, 150 GHz, and 280 GHz), a situation similar to that found in the "Southern Hole." We show that two ~20-day flights of the SPIDER instrument can constrain the amplitude of the B-mode signal to r<0.03 (99% CL) even when foreground contamination is taken into account. In the absence of foregrounds, the same limit can be reached after one 20-day flight., Comment: 29 pages, 8 figures, 4 tables; v2: matches published version, flight schedule updated, two typos fixed in Table 2, references and minor clarifications added, results unchanged

Published

2011

15. Design and performance of the Spider instrument

Author

Runyan, M. C., Ade, P. A. R., Amiri, M., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L., Gandilo, N., Golwala, S. R., Gudmundsson, J. E., Hasselfield, M., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Morford, T. A., Montroy, T. E., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Schenker, M. A., Shariff, J., Soler, J. D., Trangsrud, A., Tucker, R. S., Tucker, C., Turner, A., Runyan, M. C., Ade, P. A. R., Amiri, M., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L., Gandilo, N., Golwala, S. R., Gudmundsson, J. E., Hasselfield, M., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Morford, T. A., Montroy, T. E., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Schenker, M. A., Shariff, J., Soler, J. D., Trangsrud, A., Tucker, R. S., Tucker, C., and Turner, A.

Abstract

Here we describe the design and performance of the Spider instrument. Spider is a balloon-borne cosmic microwave background polarization imager that will map part of the sky at 90, 145, and 280 GHz with sub-degree resolution and high sensitivity. This paper discusses the general design principles of the instrument inserts, mechanical structures, optics, focal plane architecture, thermal architecture, and magnetic shielding of the TES sensors and SQUID multiplexer. We also describe the optical, noise, and magnetic shielding performance of the 145 GHz prototype instrument insert., Comment: 12 pages, 5 figures, Proceedings of SPIE, Astronomical Telescopes and Instrumentation 2010, San Diego, CA

Published

2011

16. Thermal architecture for the SPIDER flight cryostat

Author

Gudmundsson, J. E., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Halpern, M., Hasselfield, M., Helson, K. R., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Gudmundsson, J. E., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Halpern, M., Hasselfield, M., Helson, K. R., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., and Turner, A. D.

Abstract

We describe the cryogenic system for SPIDER, a balloon-borne microwave polarimeter that will map 8% of the sky with degree-scale angular resolution. The system consists of a 1284 L liquid helium cryostat and a 16 L capillary-filled superfluid helium tank, which provide base operating temperatures of 4 K and 1.5 K, respectively. Closed-cycle helium-3 adsorption refrigerators supply sub-Kelvin cooling power to multiple focal planes, which are housed in monochromatic telescope inserts. The main helium tank is suspended inside the vacuum vessel with thermally insulating fiberglass flexures, and shielded from thermal radiation by a combination of two vapor cooled shields and multi-layer insulation. This system allows for an extremely low instrumental background and a hold time in excess of 25 days. The total mass of the cryogenic system, including cryogens, is approximately 1000 kg. This enables conventional long duration balloon flights. We will discuss the design, thermal analysis, and qualification of the cryogenic system., Comment: 11 pages, 4 figures; as published in the conference proceedings for SPIE Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy V (2010)

Published

2011

17. SPIDER: a balloon-borne CMB polarimeter for large angular scales

Author

Filippini, J. P., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Doré, O., Farhang, M., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Gudmundsson, J. E., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Filippini, J. P., Ade, P. A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Doré, O., Farhang, M., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Gudmundsson, J. E., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., and Turner, A. D.

Abstract

We describe SPIDER, a balloon-borne instrument to map the polarization of the millimeter-wave sky with degree angular resolution. Spider consists of six monochromatic refracting telescopes, each illuminating a focal plane of large-format antenna-coupled bolometer arrays. A total of 2,624 superconducting transition-edge sensors are distributed among three observing bands centered at 90, 150, and 280 GHz. A cold half-wave plate at the aperture of each telescope modulates the polarization of incoming light to control systematics. Spider's first flight will be a 20-30-day Antarctic balloon campaign in December 2011. This flight will map \sim8% of the sky to achieve unprecedented sensitivity to the polarization signature of the gravitational wave background predicted by inflationary cosmology. The Spider mission will also serve as a proving ground for these detector technologies in preparation for a future satellite mission., Comment: 12 pages, 6 figures; as published in the conference proceedings for SPIE Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy V (2010)

Published

2011

18. Spider Optimization II: Optical, Magnetic and Foreground Effects

Author

O'Dea, D. T., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Dore, O., Farhang, M., Filippini, J. P., Fissel, L. M., Fraisse, A. A., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., Wiebe, D., O'Dea, D. T., Ade, P. A. R., Amiri, M., Benton, S. J., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S., Burger, B., Chiang, H. C., Clark, C. N., Contaldi, C. R., Crill, B. P., Davis, G., Dore, O., Farhang, M., Filippini, J. P., Fissel, L. M., Fraisse, A. A., Gandilo, N. N., Golwala, S., Gudmundsson, J. E., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., Rahlin, A. S., Reintsema, C., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, C., Tucker, R. S., Turner, A. D., and Wiebe, D.

Abstract

Spider is a balloon-borne instrument designed to map the polarization of the cosmic microwave background (CMB) with degree-scale resolution over a large fraction of the sky. Spider's main goal is to measure the amplitude of primordial gravitational waves through their imprint on the polarization of the CMB if the tensor-to-scalar ratio, r, is greater than 0.03. To achieve this goal, instrumental systematic errors must be controlled with unprecedented accuracy. Here, we build on previous work to use simulations of Spider observations to examine the impact of several systematic effects that have been characterized through testing and modeling of various instrument components. In particular, we investigate the impact of the non-ideal spectral response of the half-wave plates, coupling between focal plane components and the Earth's magnetic field, and beam mismatches and asymmetries. We also present a model of diffuse polarized foreground emission based on a three-dimensional model of the Galactic magnetic field and dust, and study the interaction of this foreground emission with our observation strategy and instrumental effects. We find that the expected level of foreground and systematic contamination is sufficiently low for Spider to achieve its science goals., Comment: submitted to APJ, 15 pages, 12 figures

Published

2011

19. The new generation CMB B-mode polarization experiment: POLARBEAR

Author

Collaboration, The Polarbear, Collaboration, The Polarbear, Errard, J, Ade, PAR, Anthony, A, Arnold, K, Aubin, F, Boettger, D, Borrill, J, Cantalupo, C, Dobbs, MA, Flanigan, D, Ghribi, A, Halverson, N, Hazumi, M, Holzapfel, WL, Howard, J, Hyland, P, Jaffe, A, Keating, B, Kisner, T, Kermish, Z, Lee, AT, Linder, E, Lungu, M, Matsumura, T, Miller, N, Meng, X, Myers, M, Nishino, H, O'Brient, R, O'Dea, D, Reichardt, C, Schanning, I, Shimizu, A, Shimmin, C, Shimon, M, Spieler, H, Steinbach, B, Stompor, R, Suzuki, A, Tomaru, T, Tran, HT, Tucker, C, Quealy, E, Richards, PL, Zahn, O, Collaboration, The Polarbear, Collaboration, The Polarbear, Errard, J, Ade, PAR, Anthony, A, Arnold, K, Aubin, F, Boettger, D, Borrill, J, Cantalupo, C, Dobbs, MA, Flanigan, D, Ghribi, A, Halverson, N, Hazumi, M, Holzapfel, WL, Howard, J, Hyland, P, Jaffe, A, Keating, B, Kisner, T, Kermish, Z, Lee, AT, Linder, E, Lungu, M, Matsumura, T, Miller, N, Meng, X, Myers, M, Nishino, H, O'Brient, R, O'Dea, D, Reichardt, C, Schanning, I, Shimizu, A, Shimmin, C, Shimon, M, Spieler, H, Steinbach, B, Stompor, R, Suzuki, A, Tomaru, T, Tran, HT, Tucker, C, Quealy, E, Richards, PL, and Zahn, O

Abstract

We describe the Cosmic Microwave Background (CMB) polarization experiment called Polarbear. This experiment will use the dedicated Huan Tran Telescope equipped with a powerful 1,200-bolometer array receiver to map the CMB polarization with unprecedented accuracy. We summarize the experiment, its goals, and current status.

Published

2010

20. The new generation CMB B-mode polarization experiment: POLARBEAR

Author

The Polarbear Collaboration, Errard, J., Ade, P. A. R., Anthony, A., Arnold, K., Aubin, F., Boettger, D., Borrill, J., Cantalupo, C., Dobbs, M. A., Flanigan, D., Ghribi, A., Halverson, N., Hazumi, M., Holzapfel, W. L., Howard, J., Hyland, P., Jaffe, A., Keating, B., Kisner, T., Kermish, Z., Lee, A. T., Linder, E., Lungu, M., Matsumura, T., Miller, N., Meng, X., Myers, M., Nishino, H., O'Brient, R., O'Dea, D., Reichardt, C., Schanning, I., Shimizu, A., Shimmin, C., Shimon, M., Spieler, H., Steinbach, B., Stompor, R., Suzuki, A., Tomaru, T., Tran, H. T., Tucker, C., Quealy, E., Richards, P. L., Zahn, O., The Polarbear Collaboration, Errard, J., Ade, P. A. R., Anthony, A., Arnold, K., Aubin, F., Boettger, D., Borrill, J., Cantalupo, C., Dobbs, M. A., Flanigan, D., Ghribi, A., Halverson, N., Hazumi, M., Holzapfel, W. L., Howard, J., Hyland, P., Jaffe, A., Keating, B., Kisner, T., Kermish, Z., Lee, A. T., Linder, E., Lungu, M., Matsumura, T., Miller, N., Meng, X., Myers, M., Nishino, H., O'Brient, R., O'Dea, D., Reichardt, C., Schanning, I., Shimizu, A., Shimmin, C., Shimon, M., Spieler, H., Steinbach, B., Stompor, R., Suzuki, A., Tomaru, T., Tran, H. T., Tucker, C., Quealy, E., Richards, P. L., and Zahn, O.

Abstract

We describe the Cosmic Microwave Background (CMB) polarization experiment called Polarbear. This experiment will use the dedicated Huan Tran Telescope equipped with a powerful 1,200-bolometer array receiver to map the CMB polarization with unprecedented accuracy. We summarize the experiment, its goals, and current status.

Published

2010

21. The new generation CMB B-mode polarization experiment: POLARBEAR

Author

Collaboration, The Polarbear, Collaboration, The Polarbear, Errard, J, Ade, PAR, Anthony, A, Arnold, K, Aubin, F, Boettger, D, Borrill, J, Cantalupo, C, Dobbs, MA, Flanigan, D, Ghribi, A, Halverson, N, Hazumi, M, Holzapfel, WL, Howard, J, Hyland, P, Jaffe, A, Keating, B, Kisner, T, Kermish, Z, Lee, AT, Linder, E, Lungu, M, Matsumura, T, Miller, N, Meng, X, Myers, M, Nishino, H, O'Brient, R, O'Dea, D, Reichardt, C, Schanning, I, Shimizu, A, Shimmin, C, Shimon, M, Spieler, H, Steinbach, B, Stompor, R, Suzuki, A, Tomaru, T, Tran, HT, Tucker, C, Quealy, E, Richards, PL, Zahn, O, Collaboration, The Polarbear, Collaboration, The Polarbear, Errard, J, Ade, PAR, Anthony, A, Arnold, K, Aubin, F, Boettger, D, Borrill, J, Cantalupo, C, Dobbs, MA, Flanigan, D, Ghribi, A, Halverson, N, Hazumi, M, Holzapfel, WL, Howard, J, Hyland, P, Jaffe, A, Keating, B, Kisner, T, Kermish, Z, Lee, AT, Linder, E, Lungu, M, Matsumura, T, Miller, N, Meng, X, Myers, M, Nishino, H, O'Brient, R, O'Dea, D, Reichardt, C, Schanning, I, Shimizu, A, Shimmin, C, Shimon, M, Spieler, H, Steinbach, B, Stompor, R, Suzuki, A, Tomaru, T, Tran, HT, Tucker, C, Quealy, E, Richards, PL, and Zahn, O

Abstract

We describe the Cosmic Microwave Background (CMB) polarization experiment called Polarbear. This experiment will use the dedicated Huan Tran Telescope equipped with a powerful 1,200-bolometer array receiver to map the CMB polarization with unprecedented accuracy. We summarize the experiment, its goals, and current status.

Published

2010

22. The new generation CMB B-mode polarization experiment: POLARBEAR

Author

The Polarbear Collaboration, Errard, J., Ade, P. A. R., Anthony, A., Arnold, K., Aubin, F., Boettger, D., Borrill, J., Cantalupo, C., Dobbs, M. A., Flanigan, D., Ghribi, A., Halverson, N., Hazumi, M., Holzapfel, W. L., Howard, J., Hyland, P., Jaffe, A., Keating, B., Kisner, T., Kermish, Z., Lee, A. T., Linder, E., Lungu, M., Matsumura, T., Miller, N., Meng, X., Myers, M., Nishino, H., O'Brient, R., O'Dea, D., Reichardt, C., Schanning, I., Shimizu, A., Shimmin, C., Shimon, M., Spieler, H., Steinbach, B., Stompor, R., Suzuki, A., Tomaru, T., Tran, H. T., Tucker, C., Quealy, E., Richards, P. L., Zahn, O., The Polarbear Collaboration, Errard, J., Ade, P. A. R., Anthony, A., Arnold, K., Aubin, F., Boettger, D., Borrill, J., Cantalupo, C., Dobbs, M. A., Flanigan, D., Ghribi, A., Halverson, N., Hazumi, M., Holzapfel, W. L., Howard, J., Hyland, P., Jaffe, A., Keating, B., Kisner, T., Kermish, Z., Lee, A. T., Linder, E., Lungu, M., Matsumura, T., Miller, N., Meng, X., Myers, M., Nishino, H., O'Brient, R., O'Dea, D., Reichardt, C., Schanning, I., Shimizu, A., Shimmin, C., Shimon, M., Spieler, H., Steinbach, B., Stompor, R., Suzuki, A., Tomaru, T., Tran, H. T., Tucker, C., Quealy, E., Richards, P. L., and Zahn, O.

Abstract

We describe the Cosmic Microwave Background (CMB) polarization experiment called Polarbear. This experiment will use the dedicated Huan Tran Telescope equipped with a powerful 1,200-bolometer array receiver to map the CMB polarization with unprecedented accuracy. We summarize the experiment, its goals, and current status.

Published

2010

23. Detecting the B-mode Polarisation of the CMB with Clover

Author

North, C. E., Johnson, B. R., Ade, P. A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, P. G., Challinor, A. D., Duncan, W. D., Ferreira, P. G., Gear, W. K., Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Maffei, B., Mauskopf, P., Melhuish, S. J., O'Dea, D., Parsley, S. M., Piccirillo, L., Pisano, G., Reintsema, C. D., Savini, G., Sudiwala, R., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, C., Watson, R., Withington, S., Yassin, G., Zhang, J., North, C. E., Johnson, B. R., Ade, P. A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, P. G., Challinor, A. D., Duncan, W. D., Ferreira, P. G., Gear, W. K., Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Maffei, B., Mauskopf, P., Melhuish, S. J., O'Dea, D., Parsley, S. M., Piccirillo, L., Pisano, G., Reintsema, C. D., Savini, G., Sudiwala, R., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, C., Watson, R., Withington, S., Yassin, G., and Zhang, J.

Abstract

We describe the objectives, design and predicted performance of Clover, which is a ground-based experiment to measure the faint ``B-mode'' polarisation pattern in the cosmic microwave background (CMB). To achieve this goal, clover will make polarimetric observations of approximately 1000 deg^2 of the sky in spectral bands centred on 97, 150 and 225 GHz. The observations will be made with a two-mirror compact range antenna fed by profiled corrugated horns. The telescope beam sizes for each band are 7.5, 5.5 and 5.5 arcmin, respectively. The polarisation of the sky will be measured with a rotating half-wave plate and stationary analyser, which will be an orthomode transducer. The sky coverage combined with the angular resolution will allow us to measure the angular power spectra between 20 < l < 1000. Each frequency band will employ 192 single polarisation, photon noise limited TES bolometers cooled to 100 mK. The background-limited sensitivity of these detector arrays will allow us to constrain the tensor-to-scalar ratio to 0.026 at 3sigma, assuming any polarised foreground signals can be subtracted with minimal degradation to the 150 GHz sensitivity. Systematic errors will be mitigated by modulating the polarisation of the sky signals with the rotating half-wave plate, fast azimuth scans and periodic telescope rotations about its boresight. The three spectral bands will be divided into two separate but nearly identical instruments - one for 97 GHz and another for 150 and 225 GHz. The two instruments will be sited on identical three-axis mounts in the Atacama Desert in Chile near Pampa la Bola. Observations are expected to begin in late 2009., Comment: 5 pages, 3 figures. To appear in the proceedings of the XXXXIIIrd Rencontres de Moriond "Cosmology". Figure 1 updated

Published

2008

24. Detecting the B-mode Polarisation of the CMB with Clover

Author

North, C. E., Johnson, B. R., Ade, P. A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, P. G., Challinor, A. D., Duncan, W. D., Ferreira, P. G., Gear, W. K., Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Maffei, B., Mauskopf, P., Melhuish, S. J., O'Dea, D., Parsley, S. M., Piccirillo, L., Pisano, G., Reintsema, C. D., Savini, G., Sudiwala, R., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, C., Watson, R., Withington, S., Yassin, G., Zhang, J., North, C. E., Johnson, B. R., Ade, P. A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, P. G., Challinor, A. D., Duncan, W. D., Ferreira, P. G., Gear, W. K., Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Maffei, B., Mauskopf, P., Melhuish, S. J., O'Dea, D., Parsley, S. M., Piccirillo, L., Pisano, G., Reintsema, C. D., Savini, G., Sudiwala, R., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, C., Watson, R., Withington, S., Yassin, G., and Zhang, J.

Abstract

We describe the objectives, design and predicted performance of Clover, which is a ground-based experiment to measure the faint ``B-mode'' polarisation pattern in the cosmic microwave background (CMB). To achieve this goal, clover will make polarimetric observations of approximately 1000 deg^2 of the sky in spectral bands centred on 97, 150 and 225 GHz. The observations will be made with a two-mirror compact range antenna fed by profiled corrugated horns. The telescope beam sizes for each band are 7.5, 5.5 and 5.5 arcmin, respectively. The polarisation of the sky will be measured with a rotating half-wave plate and stationary analyser, which will be an orthomode transducer. The sky coverage combined with the angular resolution will allow us to measure the angular power spectra between 20 < l < 1000. Each frequency band will employ 192 single polarisation, photon noise limited TES bolometers cooled to 100 mK. The background-limited sensitivity of these detector arrays will allow us to constrain the tensor-to-scalar ratio to 0.026 at 3sigma, assuming any polarised foreground signals can be subtracted with minimal degradation to the 150 GHz sensitivity. Systematic errors will be mitigated by modulating the polarisation of the sky signals with the rotating half-wave plate, fast azimuth scans and periodic telescope rotations about its boresight. The three spectral bands will be divided into two separate but nearly identical instruments - one for 97 GHz and another for 150 and 225 GHz. The two instruments will be sited on identical three-axis mounts in the Atacama Desert in Chile near Pampa la Bola. Observations are expected to begin in late 2009., Comment: 5 pages, 3 figures. To appear in the proceedings of the XXXXIIIrd Rencontres de Moriond "Cosmology". Figure 1 updated

Published

2008

25. Development of an Interoperable, Survivable Pilot DCE Application.

Author

DEFENCE SCIENCE AND TECHNOLOGY ORGANIZATION CANBERRA (AUSTRALIA), McClure, B., O'Dea, D., DEFENCE SCIENCE AND TECHNOLOGY ORGANIZATION CANBERRA (AUSTRALIA), McClure, B., and O'Dea, D.

Abstract

This report discusses some problems encountered in developing and porting a pilot Distributed Computing Environment (DCE) program to several different platforms. The pilot program demonstrates the interoperability, portability and survivability features of OSF's DCE.

Published

1995

26. Clover – Measuring the CMB B-mode polarisation

Author

Karpov, A., North, C. E., Ade, Peter A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, P. G., Challinor, A. D., Duncan, W. D., Ferreira, P., Gear, Walter Kieran, Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Johnson, B. R., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Lewis, S., Maffei, B., Martinis, L., Mauskopf, Philip Daniel, Melhuish, S. J., O’Dea, D., Parsley, S. M., Piccirillo, L., Pisano, Giampaolo, Reintsema, C. D., Savini, Giorgio, Sudiwala, Rashmikant V., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, Carole, Watson, R., Withington, S., Yassin, G., Zhang, Jin, Karpov, A., North, C. E., Ade, Peter A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, P. G., Challinor, A. D., Duncan, W. D., Ferreira, P., Gear, Walter Kieran, Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Johnson, B. R., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Lewis, S., Maffei, B., Martinis, L., Mauskopf, Philip Daniel, Melhuish, S. J., O’Dea, D., Parsley, S. M., Piccirillo, L., Pisano, Giampaolo, Reintsema, C. D., Savini, Giorgio, Sudiwala, Rashmikant V., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, Carole, Watson, R., Withington, S., Yassin, G., and Zhang, Jin

27. Clover - Measuring the CMB B-mode polarization

Author

Karpov, A., North, C. E., Ade, Peter A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, Paolo G., Challinor, A. D., Duncan, W. D., Ferreira, P., Gear, W. K., Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Johnson, B. R., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Lewis, S., Maffei, B., Marinis, L., Mauskopf, Philip Daniel, Melhuish, S. J., O'Dea, D., Parsley, Stephen M., Piccirillo, L., Pisano, G., Reintsema, C. D., Savini, Giorgio, Sudiwala, Rashmikant V., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, Charles Robert, Watson, R., Withington, S., Yassin, G., Zhang, Jin, Karpov, A., North, C. E., Ade, Peter A. R., Audley, M. D., Baines, C., Battye, R. A., Brown, M. L., Cabella, P., Calisse, Paolo G., Challinor, A. D., Duncan, W. D., Ferreira, P., Gear, W. K., Glowacka, D., Goldie, D. J., Grimes, P. K., Halpern, M., Haynes, V., Hilton, G. C., Irwin, K. D., Johnson, B. R., Jones, M. E., Lasenby, A. N., Leahy, P. J., Leech, J., Lewis, S., Maffei, B., Marinis, L., Mauskopf, Philip Daniel, Melhuish, S. J., O'Dea, D., Parsley, Stephen M., Piccirillo, L., Pisano, G., Reintsema, C. D., Savini, Giorgio, Sudiwala, Rashmikant V., Sutton, D., Taylor, A. C., Teleberg, G., Titterington, D., Tsaneva, V., Tucker, Charles Robert, Watson, R., Withington, S., Yassin, G., and Zhang, Jin

Abstract

We describe the objectives, design and predicted performance of Clover, a fully-funded, UK-led experiment to measure the B-mode polarisation of the Cosmic Microwave Background (CMB). Three individual telescopes will operate at 97, 150 and 225 GHz, each populated by up to 256 horns. The detectors, TES bolometers, are limited by unavoidable photon noise, and coupled to an optical design which gives very low systematic errors, particularly in cross-polarisation. The telescopes will sit on three-axis mounts on a site in the Atacama Desert. The angular resolution of around 8´ and sky coverage of around 1000 deg2 provide multipole coverage of 20<ℓ<1000. Combined with the high sensitivity, this should allow the B-mode signal to be measured (or constrained) down to a level corresponding to a tensor-to-scalar ratio of r = 0.01, providing the emission from polarised foregrounds can be subtracted. This in turn will allow constraints to be placed on the energy scale of inflation, providing an unprecedented insight into the early history of the Universe.

28. Thermal architecture for the SPIDER flight cryostat

Author

Holland, Wayne S., Zmuidzinas, Jonas, Gudmundsson, J. E., Ade, Peter A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., Farhang, M., Filippini, J., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, Carole Elizabeth, Tucker, R. S., Turner, A. D., Holland, Wayne S., Zmuidzinas, Jonas, Gudmundsson, J. E., Ade, Peter A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., Farhang, M., Filippini, J., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, Carole Elizabeth, Tucker, R. S., and Turner, A. D.

Abstract

We describe the cryogenic system for SPIDER, a balloon-borne microwave polarimeter that will map 8% of the sky with degree-scale angular resolution. The system consists of a 1284 L liquid helium cryostat and a 16 L capillary-filled superfluid helium tank, which provide base operating temperatures of 4 K and 1.5 K, respectively. Closed-cycle 3He adsorption refrigerators supply sub-Kelvin cooling power to multiple focal planes, which are housed in monochromatic telescope inserts. The main helium tank is suspended inside the vacuum vessel with thermally insulating fiberglass flexures, and shielded from thermal radiation by a combination of two vapor cooled shields and multi-layer insulation. This system allows for an extremely low instrumental background and a hold time in excess of 25 days. The total mass of the cryogenic system, including cryogens, is approximately 1000 kg. This enables conventional long duration balloon flights. We will discuss the design, thermal analysis, and qualification of the cryogenic system.

29. SPIDER: a balloon-borne CMB polarimeter for large angular scales

Author

Holland, Wayne S, Zmuidzinas, Jonas, Filippini, J. P., Ade, Peter A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., Farhang, M., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Gudmundsson, J. E., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, Carole Elizabeth, Tucker, R. S., Turner, A. D., Holland, Wayne S, Zmuidzinas, Jonas, Filippini, J. P., Ade, Peter A. R., Amiri, M., Benton, S. J., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Burger, B., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., Farhang, M., Fissel, L. M., Gandilo, N. N., Golwala, S. R., Gudmundsson, J. E., Halpern, M., Hasselfield, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Montroy, T. E., Morford, T. A., Netterfield, C. B., O'Dea, D. T., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Runyan, M. C., Schenker, M. A., Shariff, J. A., Soler, J. D., Trangsrud, A., Tucker, Carole Elizabeth, Tucker, R. S., and Turner, A. D.

Abstract

We describe SPIDER, a balloon-borne instrument to map the polarization of the millimeter-wave sky with degree angular resolution. Spider consists of six monochromatic refracting telescopes, each illuminating a focal plane of large-format antenna-coupled bolometer arrays. A total of 2,624 superconducting transition-edge sensors are distributed among three observing bands centered at 90, 150, and 280 GHz. A cold half-wave plate at the aperture of each telescope modulates the polarization of incoming light to control systematics. SPIDER's first flight will be a 20-30-day Antarctic balloon campaign in December 2011. This flight will map ~8% of the sky to achieve unprecedented sensitivity to the polarization signature of the gravitational wave background predicted by inflationary cosmology. The SPIDER mission will also serve as a proving ground for these detector technologies in preparation for a future satellite mission.

30. Ultra high energy cosmology with POLARBEAR

Author

Keating, B., Moyerman, S., Boettger, D., Edwards, J., Fuller, G., Matsuda, F., Miller, N., Paar, H., Rebeiz, G., Schanning, I., Shimon, M., Stebor, N., Arnold, K., Falnigan, D., Holzapfel, W., Howard, J., Kermish, Z., Lee, A., Lungu, M., Myers, M., Nishino, H., O'Brient, R., Quealy, E., Reichhardt, C., Richards, P., Shimmin, C., Steinbach, B., Suzuki, A., Zahn, O., Borrill, J., Cantalupo, C., Kisner, E., Linder, E., Sholl, M., Spieler, H., Anthony, A., Halverson, N., Errard, J., Fabbian, G., Le Jeune, M., Stompor, R., Jaffe, A., O'Dea, D., Chinone, Y., Hasegawa, M., Hazumi, M., Matsamura, T., Morii, H., Shimizu, A., Tomaru, T., Hyland, P., Dobbs, M., Ade, Peter A. R., Grainger, William F., Tucker, Carole, Keating, B., Moyerman, S., Boettger, D., Edwards, J., Fuller, G., Matsuda, F., Miller, N., Paar, H., Rebeiz, G., Schanning, I., Shimon, M., Stebor, N., Arnold, K., Falnigan, D., Holzapfel, W., Howard, J., Kermish, Z., Lee, A., Lungu, M., Myers, M., Nishino, H., O'Brient, R., Quealy, E., Reichhardt, C., Richards, P., Shimmin, C., Steinbach, B., Suzuki, A., Zahn, O., Borrill, J., Cantalupo, C., Kisner, E., Linder, E., Sholl, M., Spieler, H., Anthony, A., Halverson, N., Errard, J., Fabbian, G., Le Jeune, M., Stompor, R., Jaffe, A., O'Dea, D., Chinone, Y., Hasegawa, M., Hazumi, M., Matsamura, T., Morii, H., Shimizu, A., Tomaru, T., Hyland, P., Dobbs, M., Ade, Peter A. R., Grainger, William F., and Tucker, Carole

Abstract

Observations of the temperature anisotropy of the Cosmic Microwave Background (CMB) lend support to an inflationary origin of the universe, yet no direct evidence verifying inflation exists. Many current experiments are focussing on the CMB's polarization anisotropy, specifically its curl component (called "B-mode" polarization), which remains undetected. The inflationary paradigm predicts the existence of a primordial gravitational wave background that imprints a unique B-mode signature on the CMB's polarization at large angular scales. The CMB B-mode signal also encodes gravitational lensing information at smaller angular scales, bearing the imprint of cosmological large scale structures (LSS) which in turn may elucidate the properties of cosmological neutrinos. The quest for detection of these signals; each of which is orders of magnitude smaller than the CMB temperature anisotropy signal, has motivated the development of background-limited detectors with precise control of systematic effects. The POLARBEAR experiment is designed to perform a deep search for the signature of gravitational waves from inflation and to characterize lensing of the CMB by LSS. POLARBEAR is a 3.5 meter ground-based telescope with 3.8 arcminute angular resolution at 150 GHz. At the heart of the POLARBEAR receiver is an array featuring 1274 antenna-coupled superconducting transition edge sensor (TES) bolometers cooled to 0.25 Kelvin. POLARBEAR is designed to reach a tensor-to-scalar ratio of 0.025 after two years of observation -- more than an order of magnitude improvement over the current best results, which would test physics at energies near the GUT scale. POLARBEAR had an engineering run in the Inyo Mountains of Eastern California in 2010 and will begin observations in the Atacama Desert in Chile in 2011.

31. Design and performance of the SPIDER instrument

Author

Holland, Wayne S., Zmuidzinas, Jonas, Runyan, M. C., Ade, Peter A. R., Amiri, M., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L., Gandilo, N., Golwala, S. R., Gudmundsson, J. E., Hasselfield, M., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Morford, T. A., Montroy, T. E., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Schenker, M. A., Shariff, J., Soler, J. D., Trangsrud, A., Tucker, R. S., Tucker, Carole, Turner, A., Holland, Wayne S., Zmuidzinas, Jonas, Runyan, M. C., Ade, Peter A. R., Amiri, M., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Bonetti, J. A., Bryan, S. A., Chiang, H. C., Contaldi, C. R., Crill, B. P., Dore, O., O'Dea, D., Farhang, M., Filippini, J. P., Fissel, L., Gandilo, N., Golwala, S. R., Gudmundsson, J. E., Hasselfield, M., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K. D., Jones, W. C., Kuo, C. L., MacTavish, C. J., Mason, P. V., Morford, T. A., Montroy, T. E., Netterfield, C. B., Rahlin, A. S., Reintsema, C. D., Ruhl, J. E., Schenker, M. A., Shariff, J., Soler, J. D., Trangsrud, A., Tucker, R. S., Tucker, Carole, and Turner, A.

Abstract

Here we describe the design and performance of the SPIDER instrument. SPIDER is a balloon-borne cosmic microwave background polarization imager that will map part of the sky at 90, 145, and 280 GHz with subdegree resolution and high sensitivity. This paper discusses the general design principles of the instrument inserts, mechanical structures, optics, focal plane architecture, thermal architecture, and magnetic shielding of the TES sensors and SQUID multiplexer. We also describe the optical, noise, and magnetic shielding performance of the 145 GHz prototype instrument insert.

32. The POLARBEAR CMB polarization experiment

Author

Holland, Wayne S., Zmuidzinas, Jonas, Arnold, K., Ade, Peter A. R., Anthony, A. E., Aubin, F., Boettger, D., Borrill, J., Cantalupo, C., Dobbs, M. A., Errard, J., Flanigan, D., Ghribi, A., Halverson, N., Hazumi, M., Holzapfel, W. L., Howard, J., Hyland, P., Jaffe, A., Keating, B., Kisner, T., Kermish, Z., Lee, A. T., Linder, E., Lungu, M., Matsumura, T., Miller, N., Meng, X., Myers, M., Nishino, H., O'Brient, R., O'Dea, D., Reichardt, C., Schanning, I., Shimizu, A., Shimmin, C., Shimon, M., Spieler, H., Steinbach, B., Stompor, R., Suzuki, A., Tomaru, T., Tran, H. T., Tucker, Carole Elizabeth, Quealy, E., Richards, P. L., Zahn, O., Holland, Wayne S., Zmuidzinas, Jonas, Arnold, K., Ade, Peter A. R., Anthony, A. E., Aubin, F., Boettger, D., Borrill, J., Cantalupo, C., Dobbs, M. A., Errard, J., Flanigan, D., Ghribi, A., Halverson, N., Hazumi, M., Holzapfel, W. L., Howard, J., Hyland, P., Jaffe, A., Keating, B., Kisner, T., Kermish, Z., Lee, A. T., Linder, E., Lungu, M., Matsumura, T., Miller, N., Meng, X., Myers, M., Nishino, H., O'Brient, R., O'Dea, D., Reichardt, C., Schanning, I., Shimizu, A., Shimmin, C., Shimon, M., Spieler, H., Steinbach, B., Stompor, R., Suzuki, A., Tomaru, T., Tran, H. T., Tucker, Carole Elizabeth, Quealy, E., Richards, P. L., and Zahn, O.

Abstract

POLARBEAR is a Cosmic Microwave Background (CMB) polarization experiment that will search for evidence of inflationary gravitational waves and gravitational lensing in the polarization of the CMB. This proceeding presents an overview of the design of the instrument and the architecture of the focal plane, and shows some of the recent tests of detector performance and early data from the ongoing engineering run.