Your search keyword '"Eimer, J"' showing total 17 results

1. Tocilizumab shortens time on mechanical ventilation and length of hospital stay in patients with severe COVID-19 : a retrospective cohort study

Author

Eimer, J., Vesterbacka, J., Svensson, A.-K., Stojanovic, B., Wagrell, C., Sönnerborg, A., Nowak, P., Eimer, J., Vesterbacka, J., Svensson, A.-K., Stojanovic, B., Wagrell, C., Sönnerborg, A., and Nowak, P.

Published

2021

2. Sub-Kelvin cooling for two kilopixel bolometer arrays in the PIPER receiver

Author

Switzer, E. R., Ade, P. A. R., Baildon, T., Benford, D., Bennett, C. L., Chuss, D. T., Datta, R., Eimer, J. R., Fixsen, D. J., Gandilo, N. N., Essinger-Hileman, T. M., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L. N., McMahon, J. J., Miller, T. M., Mirel, P., Moseley, S. H., Pawlyk, S., Rodriguez, S., Sharp, E., Shirron, P., Staguhn, J. G., Sullivan, D. F., Taraschi, P., Tucker, C. E., Walts, A., Wollack, E. J., Switzer, E. R., Ade, P. A. R., Baildon, T., Benford, D., Bennett, C. L., Chuss, D. T., Datta, R., Eimer, J. R., Fixsen, D. J., Gandilo, N. N., Essinger-Hileman, T. M., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L. N., McMahon, J. J., Miller, T. M., Mirel, P., Moseley, S. H., Pawlyk, S., Rodriguez, S., Sharp, E., Shirron, P., Staguhn, J. G., Sullivan, D. F., Taraschi, P., Tucker, C. E., Walts, A., and Wollack, E. J.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne telescope mission to search for inflationary gravitational waves from the early universe. PIPER employs two 32x40 arrays of superconducting transition-edge sensors, which operate at 100 mK. An open bucket dewar of liquid helium maintains the receiver and telescope optics at 1.7 K. We describe the thermal design of the receiver and sub-kelvin cooling with a continuous adiabatic demagnetization refrigerator (CADR). The CADR operates between 70-130 mK and provides ~10 uW cooling power at 100 mK, nearly five times the loading of the two detector assemblies. We describe electronics and software to robustly control the CADR, overall CADR performance in flight-like integrated receiver testing, and practical considerations for implementation in the balloon float environment., Comment: 14 pages, 12 figures

Published

2019

3. Sub-Kelvin cooling for two kilopixel bolometer arrays in the PIPER receiver

Author

Switzer, E. R., Ade, P. A. R., Baildon, T., Benford, D., Bennett, C. L., Chuss, D. T., Datta, R., Eimer, J. R., Fixsen, D. J., Gandilo, N. N., Essinger-Hileman, T. M., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L. N., McMahon, J. J., Miller, T. M., Mirel, P., Moseley, S. H., Pawlyk, S., Rodriguez, S., Sharp, E., Shirron, P., Staguhn, J. G., Sullivan, D. F., Taraschi, P., Tucker, C. E., Walts, A., Wollack, E. J., Switzer, E. R., Ade, P. A. R., Baildon, T., Benford, D., Bennett, C. L., Chuss, D. T., Datta, R., Eimer, J. R., Fixsen, D. J., Gandilo, N. N., Essinger-Hileman, T. M., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L. N., McMahon, J. J., Miller, T. M., Mirel, P., Moseley, S. H., Pawlyk, S., Rodriguez, S., Sharp, E., Shirron, P., Staguhn, J. G., Sullivan, D. F., Taraschi, P., Tucker, C. E., Walts, A., and Wollack, E. J.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne telescope mission to search for inflationary gravitational waves from the early universe. PIPER employs two 32x40 arrays of superconducting transition-edge sensors, which operate at 100 mK. An open bucket dewar of liquid helium maintains the receiver and telescope optics at 1.7 K. We describe the thermal design of the receiver and sub-kelvin cooling with a continuous adiabatic demagnetization refrigerator (CADR). The CADR operates between 70-130 mK and provides ~10 uW cooling power at 100 mK, nearly five times the loading of the two detector assemblies. We describe electronics and software to robustly control the CADR, overall CADR performance in flight-like integrated receiver testing, and practical considerations for implementation in the balloon float environment., Comment: 14 pages, 12 figures

Published

2019

4. Recovery of Large Angular Scale CMB Polarization for Instruments Employing Variable-delay Polarization Modulators

Author

Miller, N. J., Chuss, D. T., Marriage, T. A., Wollack, E. J., Appel, J. W., Bennett, C. L., Eimer, J., Essinger-Hileman, T., Fixsen, D. J., Harrington, K., Moseley, S. H., Rostem, K., Switzer, E. R., Watts, D. J., Miller, N. J., Chuss, D. T., Marriage, T. A., Wollack, E. J., Appel, J. W., Bennett, C. L., Eimer, J., Essinger-Hileman, T., Fixsen, D. J., Harrington, K., Moseley, S. H., Rostem, K., Switzer, E. R., and Watts, D. J.

Abstract

Variable-delay Polarization Modulators (VPMs) are currently being implemented in experiments designed to measure the polarization of the cosmic microwave background on large angular scales because of their capability for providing rapid, front-end polarization modulation and control over systematic errors. Despite the advantages provided by the VPM, it is important to identify and mitigate any time-varying effects that leak into the synchronously modulated component of the signal. In this paper, the effect of emission from a $300$ K VPM on the system performance is considered and addressed. Though instrument design can greatly reduce the influence of modulated VPM emission, some residual modulated signal is expected. VPM emission is treated in the presence of rotational misalignments and temperature variation. Simulations of time-ordered data are used to evaluate the effect of these residual errors on the power spectrum. The analysis and modeling in this paper guides experimentalists on the critical aspects of observations using VPMs as front-end modulators. By implementing the characterizations and controls as described, front-end VPM modulation can be very powerful for mitigating $1/f$ noise in large angular scale polarimetric surveys. None of the systematic errors studied fundamentally limit the detection and characterization of B-modes on large scales for a tensor-to-scalar ratio of $r=0.01$. Indeed, $r<0.01$ is achievable with commensurately improved characterizations and controls., Comment: 13 pages, 13 figures, 1 table, matches published version

Published

2015

5. Cosmology Large Angular Scale Surveyor (CLASS) Focal Plane Development

Author

Chuss, D. T., Ali, A., Amiri, M., Appel, J., Bennett, C. L., Colazo, F., Denis, K. L., Dünner, R., Essinger-Hileman, T., Eimer, J., Fluxa, P., Gothe, D., Halpern, M., Harrington, K., Hilton, G., Hinshaw, G., Hubmayr, J., Iuliano, J., Marriage, T. A., Miller, N., Moseley, S. H., Mumby, G., Petroff, M., Reintsema, C., Rostem, K., U-Yen, K., Watts, D., Wagner, E., Wollack, E. J., Xu, Z., Zeng, L., Chuss, D. T., Ali, A., Amiri, M., Appel, J., Bennett, C. L., Colazo, F., Denis, K. L., Dünner, R., Essinger-Hileman, T., Eimer, J., Fluxa, P., Gothe, D., Halpern, M., Harrington, K., Hilton, G., Hinshaw, G., Hubmayr, J., Iuliano, J., Marriage, T. A., Miller, N., Moseley, S. H., Mumby, G., Petroff, M., Reintsema, C., Rostem, K., U-Yen, K., Watts, D., Wagner, E., Wollack, E. J., Xu, Z., and Zeng, L.

Abstract

The Cosmology Large Angular Scale Surveyor (CLASS) will measure the polarization of the Cosmic Microwave Background to search for and characterize the polarized signature of inflation. CLASS will operate from the Atacama Desert and observe $\sim$70% of the sky. A variable-delay polarization modulator (VPM) modulates the polarization at $\sim$10 Hz to suppress the 1/f noise of the atmosphere and enable the measurement of the large angular scale polarization modes. The measurement of the inflationary signal across angular scales that span both the recombination and reionization features allows a test of the predicted shape of the polarized angular power spectra in addition to a measurement of the energy scale of inflation. CLASS is an array of telescopes covering frequencies of 38, 93, 148, and 217 GHz. These frequencies straddle the foreground minimum and thus allow the extraction of foregrounds from the primordial signal. Each focal plane contains feedhorn-coupled transition-edge sensors that simultaneously detect two orthogonal linear polarizations. The use of single-crystal silicon as the dielectric for the on-chip transmission lines enables both high efficiency and uniformity in fabrication. Integrated band definition has been implemented that both controls the bandpass of the single mode transmission on the chip and prevents stray light from coupling to the detectors., Comment: 7 pages, 5 figures, accepted by the Journal of Low Temperature Physics

Published

2015

6. Cosmology Large Angular Scale Surveyor (CLASS) Focal Plane Development

Author

Chuss, D. T., Ali, A., Amiri, M., Appel, J., Bennett, C. L., Colazo, F., Denis, K. L., Dünner, R., Essinger-Hileman, T., Eimer, J., Fluxa, P., Gothe, D., Halpern, M., Harrington, K., Hilton, G., Hinshaw, G., Hubmayr, J., Iuliano, J., Marriage, T. A., Miller, N., Moseley, S. H., Mumby, G., Petroff, M., Reintsema, C., Rostem, K., U-Yen, K., Watts, D., Wagner, E., Wollack, E. J., Xu, Z., Zeng, L., Chuss, D. T., Ali, A., Amiri, M., Appel, J., Bennett, C. L., Colazo, F., Denis, K. L., Dünner, R., Essinger-Hileman, T., Eimer, J., Fluxa, P., Gothe, D., Halpern, M., Harrington, K., Hilton, G., Hinshaw, G., Hubmayr, J., Iuliano, J., Marriage, T. A., Miller, N., Moseley, S. H., Mumby, G., Petroff, M., Reintsema, C., Rostem, K., U-Yen, K., Watts, D., Wagner, E., Wollack, E. J., Xu, Z., and Zeng, L.

Abstract

The Cosmology Large Angular Scale Surveyor (CLASS) will measure the polarization of the Cosmic Microwave Background to search for and characterize the polarized signature of inflation. CLASS will operate from the Atacama Desert and observe $\sim$70% of the sky. A variable-delay polarization modulator (VPM) modulates the polarization at $\sim$10 Hz to suppress the 1/f noise of the atmosphere and enable the measurement of the large angular scale polarization modes. The measurement of the inflationary signal across angular scales that span both the recombination and reionization features allows a test of the predicted shape of the polarized angular power spectra in addition to a measurement of the energy scale of inflation. CLASS is an array of telescopes covering frequencies of 38, 93, 148, and 217 GHz. These frequencies straddle the foreground minimum and thus allow the extraction of foregrounds from the primordial signal. Each focal plane contains feedhorn-coupled transition-edge sensors that simultaneously detect two orthogonal linear polarizations. The use of single-crystal silicon as the dielectric for the on-chip transmission lines enables both high efficiency and uniformity in fabrication. Integrated band definition has been implemented that both controls the bandpass of the single mode transmission on the chip and prevents stray light from coupling to the detectors., Comment: 7 pages, 5 figures, accepted by the Journal of Low Temperature Physics

Published

2015

7. Recovery of Large Angular Scale CMB Polarization for Instruments Employing Variable-delay Polarization Modulators

Author

Miller, N. J., Chuss, D. T., Marriage, T. A., Wollack, E. J., Appel, J. W., Bennett, C. L., Eimer, J., Essinger-Hileman, T., Fixsen, D. J., Harrington, K., Moseley, S. H., Rostem, K., Switzer, E. R., Watts, D. J., Miller, N. J., Chuss, D. T., Marriage, T. A., Wollack, E. J., Appel, J. W., Bennett, C. L., Eimer, J., Essinger-Hileman, T., Fixsen, D. J., Harrington, K., Moseley, S. H., Rostem, K., Switzer, E. R., and Watts, D. J.

Abstract

Variable-delay Polarization Modulators (VPMs) are currently being implemented in experiments designed to measure the polarization of the cosmic microwave background on large angular scales because of their capability for providing rapid, front-end polarization modulation and control over systematic errors. Despite the advantages provided by the VPM, it is important to identify and mitigate any time-varying effects that leak into the synchronously modulated component of the signal. In this paper, the effect of emission from a $300$ K VPM on the system performance is considered and addressed. Though instrument design can greatly reduce the influence of modulated VPM emission, some residual modulated signal is expected. VPM emission is treated in the presence of rotational misalignments and temperature variation. Simulations of time-ordered data are used to evaluate the effect of these residual errors on the power spectrum. The analysis and modeling in this paper guides experimentalists on the critical aspects of observations using VPMs as front-end modulators. By implementing the characterizations and controls as described, front-end VPM modulation can be very powerful for mitigating $1/f$ noise in large angular scale polarimetric surveys. None of the systematic errors studied fundamentally limit the detection and characterization of B-modes on large scales for a tensor-to-scalar ratio of $r=0.01$. Indeed, $r<0.01$ is achievable with commensurately improved characterizations and controls., Comment: 13 pages, 13 figures, 1 table, matches published version

Published

2015

8. The primordial inflation polarization explorer: science from circular polarization measurements

Author

Switzer, Eric, Ade, P., Benford, D. J., Bennett, C. L., Chuss, D. T., Dotson, J. L., Eimer, J., Fixsen, D. J., Halpern, M., Hinshaw, G. F., Irwin, K., Jhabvala, C., Johnson, B., Kogut, A. J., Lazear, J., Mirel, P., Moseley, S. H., Staguhn, J., Tucker, C. E., Weston, A., Wollack, E., Switzer, Eric, Ade, P., Benford, D. J., Bennett, C. L., Chuss, D. T., Dotson, J. L., Eimer, J., Fixsen, D. J., Halpern, M., Hinshaw, G. F., Irwin, K., Jhabvala, C., Johnson, B., Kogut, A. J., Lazear, J., Mirel, P., Moseley, S. H., Staguhn, J., Tucker, C. E., Weston, A., and Wollack, E.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne CMB polarimeter designed to constrain the B-mode signature of cosmological inflation. Sequential one-day flights from Northern- and Southern- Hemisphere sites will yield maps of Stokes I, Q, U and V at 200, 270, 350 and 600 GHz over 85% of the sky. The full optical path is cooled to 1.5 K by liquid helium in the ARCADE bucket dewar, and a variable-delay polarization modulator (VPM) at the front of the optics modulates the polarization response. Independent Q and U cameras each have two 32x40 Transition Edge Sensor array receivers. In addition to its primary inflationary science goal, PIPER will also measure the circular (Stokes V) polarization to a depth similar to that of the primary linear polarization. The circular polarization has received relatively little attention in large-area surveys, with constraints from the 1980’s and recent results by the Milan Polarimeter. Astrophysical circular polarization is generally tied to the presence of magnetic fields, either in relativistic plasmas or Zeeman splitting of resonances. These effects are thought to be undetectable at PIPER's frequencies and resolution, despite the depth. The expectation of a null result makes the deep Stokes V map a good cross-check for experimental systematics. More fundamentally, the fact that the sky is expected to be dark in Stokes V makes it a sector sensitive to processes such as Lorentz-violating terms in the standard model or magnetic fields in the CMB era.

9. The Primordial Inflation Polarization Explorer (PIPER): receiver design and performance

Author

Switzer, E., Ade, P., Baildon, T., Bellis, N., Benford, D., Bennett, C., Chuss, D., Datta, R., Eimer, J., Fixsen, D., Gandilo, N., Essinger-Hileman, T., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L., McMahon, J., Miller, T., Mirel, P., Pawlyk, S., Rodriguez, S., Sharp, E., Staguhn, J., Sullivan, D., Tarachi, P., Tucker, C., Walts, A., Wollack, E., Switzer, E., Ade, P., Baildon, T., Bellis, N., Benford, D., Bennett, C., Chuss, D., Datta, R., Eimer, J., Fixsen, D., Gandilo, N., Essinger-Hileman, T., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L., McMahon, J., Miller, T., Mirel, P., Pawlyk, S., Rodriguez, S., Sharp, E., Staguhn, J., Sullivan, D., Tarachi, P., Tucker, C., Walts, A., and Wollack, E.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument that will probe the epoch of reionization and search for the signature of inflation through large angular scale measurements of the linear polarization of the cosmic microwave background in four frequency bands from 200 to 600 GHz. The PIPER receiver couples two 32x40 arrays of transition-edge sensors (TES) to cryogenic telescope optics. The optics are maintained at < 3 K using superfluid pumps in an open bucket of liquid helium. The receiver houses the detector arrays and sub-K cooler in a superfluid-tight enclosure. We describe several aspects of the receiver design and performance: 1) the thermal design of the receiver and cooling to 100 mK with a continuous adiabatic demagnetization refrigerator (CADR) 2) performance of the TES arrays in the integrated receiver, 3) design of the reimaging optics and superfluid-tight windows. The PIPER receiver is the first implementation of kilo-pixel TES bolometer arrays combined with a continuous ADR operating at 100 mK, which provide 10 uW cooling....

10. The Primordial Inflation Polarization Explorer (PIPER): 2019 flight and telescope performance

Author

Essinger-Hileman, T., Ade, P. A., Baildon, T., Bellis, N., Benford, D., Bennett, C., Chuss, D., Datta, R., Eimer, J., Fixsen, D., Gandilo, N., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L., McMahon, J., Miller, T., Mirel, P., Moseley, S., Pawlyk, S., Rodriguez, S., Sharp, E., Shirron, P., Staguhn, J., Sullivan, D., Switzer, E., Taraschi, P., Tucker, C., Walts, A., Wollack, E, Essinger-Hileman, T., Ade, P. A., Baildon, T., Bellis, N., Benford, D., Bennett, C., Chuss, D., Datta, R., Eimer, J., Fixsen, D., Gandilo, N., Halpern, M., Hilton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L., McMahon, J., Miller, T., Mirel, P., Moseley, S., Pawlyk, S., Rodriguez, S., Sharp, E., Shirron, P., Staguhn, J., Sullivan, D., Switzer, E., Taraschi, P., Tucker, C., Walts, A., and Wollack, E

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument that will probe the epoch of reionization and search for the signature of inflation through large angular scale measurements of the linear polarization of the cosmic microwave background in four frequency bands from 200 to 600 GHz. PIPER consists of co-pointed twin cryogenic telescopes operating in an open liquid helium bucket dewar that upon achieving float altitude cool below a temperature of 3 K. Variable-delay polarization modulators (VPMs) provide sensitivity to circular polarization for systematic error control, along with one linear polarization component per telescope. The twin telescopes provide simultaneous sensitivity to Stokes I, Q, U, and V. On 14 October 2019, PIPER flew from Fort Sumner, NM, configured to observe in a band centered at 200 GHz. The flight lasted 13 hours, reaching an altitude of 30.2 km. Failure of an observation hatch to open upon reaching float altitude prevented astrophysical observations; however, the VPMs and telescope cryogenics were operated successfully. Here we report on the 2019 PIPER flight and the performance of these systems at float....

11. The Primordial Inflation Polarization Explorer (PIPER): Preflight characterization of the detector arrays

Author

Datta, R., Ade, P., Baildon, T., Bellis, N., Benford, D., Bennett, C., Chuss, D., Eimer, J., Fixsen, D., Gandilo, N., Essinger-Hileman, T., Halpern, M., HIlton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L., McMahon, J., Miller, T., Mirel, P., Moseley, S., Pawlyk, S., Rodriquez, R., Sharp, E., Shirron, P., Staguhn, J., Sullivan, D., Switzer, E., Taraschi, P., Tucker, C., Walts, A., Wollack, E., Datta, R., Ade, P., Baildon, T., Bellis, N., Benford, D., Bennett, C., Chuss, D., Eimer, J., Fixsen, D., Gandilo, N., Essinger-Hileman, T., Halpern, M., HIlton, G., Irwin, K., Jhabvala, C., Kimball, M., Kogut, A., Lazear, J., Lowe, L., McMahon, J., Miller, T., Mirel, P., Moseley, S., Pawlyk, S., Rodriquez, R., Sharp, E., Shirron, P., Staguhn, J., Sullivan, D., Switzer, E., Taraschi, P., Tucker, C., Walts, A., and Wollack, E.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument that will probe the epoch of reionization and search for the signature of inflation through large angular scale measurements of the linear polarization of the cosmic microwave background in four frequency bands from 200 to 600 GHz. The sky is imaged on to two 32x40 pixel arrays of time-domain multiplexed Transition-Edge Sensor (TES) bolometers operating at a bath temperature of 100 mK to achieve background-limited sensitivity. Each kilopixel array is indium-bump-bonded to a 2D superconducting quantum interference device (SQUID) time-domain multiplexer (MUX) chip and read out by warm electronics. Each pixel measures total incident power over a frequency band defined by bandpass filters in front of the array, while polarization sensitivity is provided by the upstream Variable-delay Polarization Modulators (VPMs) and analyzer grids. We present measurements of the detector dark parameters including transition temperature, saturation power, thermal conductivity, and time constants. We also present a summary of the pre-flight characterization of the detector arrays in the fully integrated flight receiver, describe the optimization of the integrated readout parameters, and the overall pixel yield of the arrays....

12. The primordial inflation polarization explorer: science from circular polarization measurements

Author

Switzer, Eric, Ade, P., Benford, D. J., Bennett, C. L., Chuss, D. T., Dotson, J. L., Eimer, J., Fixsen, D. J., Halpern, M., Hinshaw, G. F., Irwin, K., Jhabvala, C., Johnson, B., Kogut, A. J., Lazear, J., Mirel, P., Moseley, S. H., Staguhn, J., Tucker, C. E., Weston, A., Wollack, E., Switzer, Eric, Ade, P., Benford, D. J., Bennett, C. L., Chuss, D. T., Dotson, J. L., Eimer, J., Fixsen, D. J., Halpern, M., Hinshaw, G. F., Irwin, K., Jhabvala, C., Johnson, B., Kogut, A. J., Lazear, J., Mirel, P., Moseley, S. H., Staguhn, J., Tucker, C. E., Weston, A., and Wollack, E.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne CMB polarimeter designed to constrain the B-mode signature of cosmological inflation. Sequential one-day flights from Northern- and Southern- Hemisphere sites will yield maps of Stokes I, Q, U and V at 200, 270, 350 and 600 GHz over 85% of the sky. The full optical path is cooled to 1.5 K by liquid helium in the ARCADE bucket dewar, and a variable-delay polarization modulator (VPM) at the front of the optics modulates the polarization response. Independent Q and U cameras each have two 32x40 Transition Edge Sensor array receivers. In addition to its primary inflationary science goal, PIPER will also measure the circular (Stokes V) polarization to a depth similar to that of the primary linear polarization. The circular polarization has received relatively little attention in large-area surveys, with constraints from the 1980’s and recent results by the Milan Polarimeter. Astrophysical circular polarization is generally tied to the presence of magnetic fields, either in relativistic plasmas or Zeeman splitting of resonances. These effects are thought to be undetectable at PIPER's frequencies and resolution, despite the depth. The expectation of a null result makes the deep Stokes V map a good cross-check for experimental systematics. More fundamentally, the fact that the sky is expected to be dark in Stokes V makes it a sector sensitive to processes such as Lorentz-violating terms in the standard model or magnetic fields in the CMB era.

13. Phase-controlled polarization modulators

Author

Holland, Wayne S., Chuss, David T., Wollack, Edward J., Novakova, G., Pisano, Giampaolo, Eimer, J. R., Moseley, S. H., Krejny, M., U-Yen, K., Holland, Wayne S., Chuss, David T., Wollack, Edward J., Novakova, G., Pisano, Giampaolo, Eimer, J. R., Moseley, S. H., Krejny, M., and U-Yen, K.

Abstract

We report technology development of millimeter/submillimeter polarization modulators that operate by introducing a variable, controlled phase delay between two orthogonal polarization states. The variable-delay polarization modulator (VPM) operates via the introduction of a variable phase delay between two linear orthogonal polarization states, resulting in a variable mapping of a single linear polarization into a combination of that Stokes parameter and circular (Stokes V) polarization. Characterization of a prototype VPM is presented at 350 and 3000 microns. We also describe a modulator in which a variable phase delay is introduced between right- and left- circular polarization states. In this architecture, linear polarization is fully modulated. Each of these devices consists of a polarization diplexer parallel to and in front of a movable mirror. Modulation involves sub-wavelength translations of the mirror that change the magnitude of the phase delay.

14. Current status of the PIPER experiment

Author

Johnson, Bradley, Ade, Peter A. R., Benford, D., Bennett, C., Chuss, D., Dotson, J., Eimer, J., Fixsen, D., Halpern, M, Hilton, G., Hinderks, J., Hinshaw, G., Irwin, K., Jethava, N., Jhabvala, C., Kogut, A., Lazear, J., Lowe, L., Miller, T., Mirel, P., Moseley, H., Rodriguez, S., Rostem, K., Sharp, E., Staguhn, J., Tucker, Carole Elizabeth, Voellmer, G., Wollack, E., Zeng, L., Johnson, Bradley, Ade, Peter A. R., Benford, D., Bennett, C., Chuss, D., Dotson, J., Eimer, J., Fixsen, D., Halpern, M, Hilton, G., Hinderks, J., Hinshaw, G., Irwin, K., Jethava, N., Jhabvala, C., Kogut, A., Lazear, J., Lowe, L., Miller, T., Mirel, P., Moseley, H., Rodriguez, S., Rostem, K., Sharp, E., Staguhn, J., Tucker, Carole Elizabeth, Voellmer, G., Wollack, E., and Zeng, L.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument to measure the polarization of the cosmic microwave background in search of the expected signature of primordial gravity waves excited during an inflationary epoch shortly after the Big Bang. PIPER consists of two co-aligned telescopes, one sensitive to the Q Stokes parameter and the other to U. Sky signals will be detected with 5120 transition edge sensor (TES) bolometers distributed in four rectangular close-packed arrays maintained at 100 mK. To maximize the sensitivity of the instrument, both telescopes are mounted within a single open bucket dewar and are maintained at 1.5 K throughout flight, with no ambient-temperature windows between the sky and the detectors. To mitigate the effects of systematic errors, the polarized sky signals will be modulated using a variable-delay polarization modulator. PIPER will observe at frequencies 200, 270, 350, and 600 GHz to separate the CMB from polarized dust emission within the Galaxy. A series of flights alternating between northern and southern hemisphere launch sites will produce nearly full-sky maps in Stokes I, Q, U, and V. I will discuss the current status and potential science returns from the PIPER project.

15. PIPER: Primordial Inflation Polarization Explorer

Author

Lazear, J., Benford, D., Chuss, D., Fixsen, D., Hinderks, J., Hinshaw, G., Jhabvala, C., Johnson, B., Kogut, A., Mirel, P., Mosely, H., Staghun, J., Wollack, E., Weston, A., Vlahacos, K., Bennett, C., Eimer, J., Halpern, M., Irwin, K., Dotson, J., Ade, Peter A. R., Tucker, Carole Elizabeth, Lazear, J., Benford, D., Chuss, D., Fixsen, D., Hinderks, J., Hinshaw, G., Jhabvala, C., Johnson, B., Kogut, A., Mirel, P., Mosely, H., Staghun, J., Wollack, E., Weston, A., Vlahacos, K., Bennett, C., Eimer, J., Halpern, M., Irwin, K., Dotson, J., Ade, Peter A. R., and Tucker, Carole Elizabeth

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument to measure the polarization of the cosmic microwave background in search of the expected signature of primordial gravity waves excited during an inflationary epoch shortly after the Big Bang. PIPER consists of two co-aligned telescopes, one sensitive to the Q Stokes parameter and the other to U. Sky signals will be detected with 5120 transition edge sensor (TES) bolometers distributed in four rectangular close-packed arrays maintained at 100 mK. To maximize the sensitivity of the instrument, both telescopes are mounted within a single open bucket dewar and are maintained at 1.5 K throughout flight, with no ambient-temperature windows between the sky and the detectors. To mitigate the effects of systematic errors, the polarized sky signals will be modulated using a variable-delay polarization modulator. PIPER will observe at frequencies 200, 270, 350, and 600 GHz to separate the CMB from polarized dust emission within the Galaxy. A series of flights alternating between northern and southern hemisphere launch sites will produce nearly full-sky maps in Stokes I, Q, U, and V. I will discuss the current status and potential science returns from the PIPER project.

16. Current status of the PIPER experiment

Author

Johnson, Bradley, Ade, Peter A. R., Benford, D., Bennett, C., Chuss, D., Dotson, J., Eimer, J., Fixsen, D., Halpern, M, Hilton, G., Hinderks, J., Hinshaw, G., Irwin, K., Jethava, N., Jhabvala, C., Kogut, A., Lazear, J., Lowe, L., Miller, T., Mirel, P., Moseley, H., Rodriguez, S., Rostem, K., Sharp, E., Staguhn, J., Tucker, Carole Elizabeth, Voellmer, G., Wollack, E., Zeng, L., Johnson, Bradley, Ade, Peter A. R., Benford, D., Bennett, C., Chuss, D., Dotson, J., Eimer, J., Fixsen, D., Halpern, M, Hilton, G., Hinderks, J., Hinshaw, G., Irwin, K., Jethava, N., Jhabvala, C., Kogut, A., Lazear, J., Lowe, L., Miller, T., Mirel, P., Moseley, H., Rodriguez, S., Rostem, K., Sharp, E., Staguhn, J., Tucker, Carole Elizabeth, Voellmer, G., Wollack, E., and Zeng, L.

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument to measure the polarization of the cosmic microwave background in search of the expected signature of primordial gravity waves excited during an inflationary epoch shortly after the Big Bang. PIPER consists of two co-aligned telescopes, one sensitive to the Q Stokes parameter and the other to U. Sky signals will be detected with 5120 transition edge sensor (TES) bolometers distributed in four rectangular close-packed arrays maintained at 100 mK. To maximize the sensitivity of the instrument, both telescopes are mounted within a single open bucket dewar and are maintained at 1.5 K throughout flight, with no ambient-temperature windows between the sky and the detectors. To mitigate the effects of systematic errors, the polarized sky signals will be modulated using a variable-delay polarization modulator. PIPER will observe at frequencies 200, 270, 350, and 600 GHz to separate the CMB from polarized dust emission within the Galaxy. A series of flights alternating between northern and southern hemisphere launch sites will produce nearly full-sky maps in Stokes I, Q, U, and V. I will discuss the current status and potential science returns from the PIPER project.

17. PIPER: Primordial Inflation Polarization Explorer

Author

Lazear, J., Benford, D., Chuss, D., Fixsen, D., Hinderks, J., Hinshaw, G., Jhabvala, C., Johnson, B., Kogut, A., Mirel, P., Mosely, H., Staghun, J., Wollack, E., Weston, A., Vlahacos, K., Bennett, C., Eimer, J., Halpern, M., Irwin, K., Dotson, J., Ade, Peter A. R., Tucker, Carole Elizabeth, Lazear, J., Benford, D., Chuss, D., Fixsen, D., Hinderks, J., Hinshaw, G., Jhabvala, C., Johnson, B., Kogut, A., Mirel, P., Mosely, H., Staghun, J., Wollack, E., Weston, A., Vlahacos, K., Bennett, C., Eimer, J., Halpern, M., Irwin, K., Dotson, J., Ade, Peter A. R., and Tucker, Carole Elizabeth

Abstract

The Primordial Inflation Polarization Explorer (PIPER) is a balloon-borne instrument to measure the polarization of the cosmic microwave background in search of the expected signature of primordial gravity waves excited during an inflationary epoch shortly after the Big Bang. PIPER consists of two co-aligned telescopes, one sensitive to the Q Stokes parameter and the other to U. Sky signals will be detected with 5120 transition edge sensor (TES) bolometers distributed in four rectangular close-packed arrays maintained at 100 mK. To maximize the sensitivity of the instrument, both telescopes are mounted within a single open bucket dewar and are maintained at 1.5 K throughout flight, with no ambient-temperature windows between the sky and the detectors. To mitigate the effects of systematic errors, the polarized sky signals will be modulated using a variable-delay polarization modulator. PIPER will observe at frequencies 200, 270, 350, and 600 GHz to separate the CMB from polarized dust emission within the Galaxy. A series of flights alternating between northern and southern hemisphere launch sites will produce nearly full-sky maps in Stokes I, Q, U, and V. I will discuss the current status and potential science returns from the PIPER project.