Your search keyword '"A. Datesman"' showing total 12 results

1. Development of x-ray microcalorimeter imaging spectrometers for the X-ray Surveyor mission concept

Author

James A. Chervenak, Frederick S. Porter, Joseph S. Adams, William B. Doriese, Wonsik Yoon, B. Mates, Thomas R. Stevenson, Kelsey M. Morgan, Johnathan D. Gard, Stephen J. Smith, Joseph W. Fowler, Dan Becker, Kazuhiro Sakai, Gene C. Hilton, Carl D. Reintsema, Joel N. Ullom, Gabriele Betancourt-Martinez, Kent D. Irwin, Saptarshi Chaudhuri, Daniel S. Swetz, Antoine R. Miniussi, Alexey Vikhlinin, Caroline A. Kilbourne, Douglas A. Bennett, John E. Sadleir, Sang Jun Lee, Nicholas A. Wakeham, Simon R. Bandler, Megan E. Eckart, Fred M. Finkbeiner, Aaron M. Datesman, Edward J. Wassell, and Richard L. Kelley

Subjects

Physics, Thermal sensors, Pixel, Spectrometer, business.industry, Reading (computer), Detector, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Multiplexing, Development (topology), 0103 physical sciences, Transition edge sensor, Aerospace engineering, 0210 nano-technology, business, 010303 astronomy & astrophysics, Remote sensing

Abstract

Four astrophysics missions are currently being studied by NASA as candidate large missions to be chosen in the 2020 astrophysics decadal survey.1 One of these missions is the “X-Ray Surveyor” (XRS), and possible configurations of this mission are currently under study by a science and technology definition team (STDT). One of the key instruments under study is an X-ray microcalorimeter, and the requirements for such an instrument are currently under discussion. In this paper we review some different detector options that exist for this instrument, and discuss what array formats might be possible. We have developed one design option that utilizes either transition-edge sensor (TES) or magnetically coupled calorimeters (MCC) in pixel array-sizes approaching 100 kilo-pixels. To reduce the number of sensors read out to a plausible scale, we have assumed detector geometries in which a thermal sensor such a TES or MCC can read out a sub-array of 20-25 individual 1” pixels. In this paper we describe the development status of these detectors, and also discuss the different options that exist for reading out the very large number of pixels.

Published

2016

2. Kilopixel backshort-under-grid arrays for the Primordial Inflation Polarization Explorer

Author

E. Sharp, Edward Leong, J. Lazear, Kent D. Irwin, Aaron M. Datesman, Edward J. Wollack, Nick Costen, Meng-Ping Chang, Samuel H. Moseley, Christine A. Jhabvala, Dominic J. Benford, Johannes Staguhn, Timothy M. Miller, Gene C. Hilton, Stephen F. Maher, Alan J. Kogut, and Regis P. Brekosky

Subjects

Physics, Fabrication, Pixel, Physics::Instrumentation and Detectors, business.industry, Bolometer, Detector, Polarization (waves), Multiplexer, law.invention, SQUID, law, Optoelectronics, Transition edge sensor, business

Abstract

We have demonstrated a kilopixel, filled, infrared bolometer array for the balloon-borne Primordial Inflation Polarization Explorer (PIPER). The array consists of three individual components assembled into a single working unit: 1) a transition-edge-sensor bolometer array with background-limited sensitivity, 2) a quarter–wavelength backshort grid, and 3) an integrated Superconducting Quantum Interference Device (SQUID) multiplexer (MUX) readout. The detector array is a filled, square–grid of suspended, one-micron thick silicon bolometers with superconducting sensors. The Backshort–Under–Grid (BUG) is a separately fabricated component serving as a backshort to each pixel in the array. The backshorts are positioned in the cavities created behind each detector by the back–etched well. The spacing of the backshort beneath the detector grid can be set from ~30-300_microns by independently adjusting process parameters during fabrication. Kilopixel arrays are directly indium–bump–bonded to a 32x40 SQUID multiplexer circuit. The array architecture is suitable for a wide range of wavelengths and applications. Detector design specific to the PIPER instrument, fabrication overview, and assembly technologies will be discussed.

Published

2014

3. Development of x-ray microcalorimeter imaging spectrometers for the X-ray Surveyor mission concept

Author

Bandler, Simon R., additional, Adams, Joseph S., additional, Chervenak, James A., additional, Datesman, Aaron M., additional, Eckart, Megan E., additional, Finkbeiner, Fred M., additional, Kelley, Richard L., additional, Kilbourne, Caroline A., additional, Betancourt-Martinez, Gabriele, additional, Miniussi, Antoine R., additional, Porter, Frederick S., additional, Sadleir, John E., additional, Sakai, Kazuhiro, additional, Smith, Stephen J., additional, Stevenson, Thomas R., additional, Wakeham, Nicholas A., additional, Wassell, Edward J., additional, Yoon, Wonsik, additional, Becker, Dan, additional, Bennett, Douglas, additional, Doriese, William B., additional, Fowler, Joseph W., additional, Gard, Johnathan D., additional, Hilton, Gene C., additional, Mates, Benjamin, additional, Morgan, Kelsey M., additional, Reintsema, Carl D., additional, Swetz, Daniel, additional, Ullom, Joel N., additional, Chaudhuri, Saptarshi, additional, Irwin, Kent D., additional, Lee, Sang-Jun, additional, and Vikhlinin, Alexey, additional

Published

2016

4. SPTpol: an instrument for CMB polarization measurements with the South Pole Telescope

Author

James A. Beall, John E. Carlstrom, T. de Haan, E. M. Leitch, Dale Li, T. Natoli, M. Lueker, Dan Becker, N. Huang, K. Vanderlinde, Kent D. Irwin, Hsiao-Mei Cho, Jason E. Austermann, Benjamin Saliwanchik, W. L. Holzapfel, Gensheng Wang, Amy N. Bender, Matt Dobbs, H. C. Chiang, Daniel P. Marrone, Lindsey Bleem, Elizabeth George, Gilbert Holder, Volodymyr Yefremenko, A. Datesman, Joseph W. Britton, T. M. Crawford, K. K. Schaffer, C. Pryke, N. W. Halverson, Jason W. Henning, A. T. Crites, Ki Won Yoon, Oliver Zahn, Joaquin Vieira, Jeff McMahon, Valentyn Novosad, Christian L. Reichardt, Antony A. Stark, S. Hoover, Lloyd Knox, Stephen Padin, Adrian T. Lee, K. A. Aird, Erik Shirokoff, John P. Nibarger, J. Kennedy, S. S. Meyer, Gene C. Hilton, R. Williamson, J. E. Ruhl, C. L. Chang, J. Mehl, Johannes Hubmayr, N. L. Harrington, Bradford Benson, Michael D. Niemack, T. E. Montroy, J. T. Sayre, K. T. Story, Ryan Keisler, Holland, Wayne S., and Zmuidzinas, J.

Subjects

Physics, Cosmology and Nongalactic Astrophysics (astro-ph.CO), 010308 nuclear & particles physics, business.industry, Gravitational wave, Cosmic microwave background, Bolometer, Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Polarization (waves), 01 natural sciences, Radio spectrum, law.invention, Optics, South Pole Telescope, Gravitational lens, law, 0103 physical sciences, Neutrino, Astrophysics - Instrumentation and Methods for Astrophysics, business, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

SPTpol is a dual-frequency polarization-sensitive camera that was deployed on the 10-meter South Pole Telescope in January 2012. SPTpol will measure the polarization anisotropy of the cosmic microwave background (CMB) on angular scales spanning an arcminute to several degrees. The polarization sensitivity of SPTpol will enable a detection of the CMB "B-mode" polarization from the detection of the gravitational lensing of the CMB by large scale structure, and a detection or improved upper limit on a primordial signal due to inflationary gravity waves. The two measurements can be used to constrain the sum of the neutrino masses and the energy scale of inflation. These science goals can be achieved through the polarization sensitivity of the SPTpol camera and careful control of systematics. The SPTpol camera consists of 768 pixels, each containing two transition-edge sensor (TES) bolometers coupled to orthogonal polarizations, and a total of 1536 bolometers. The pixels are sensitive to light in one of two frequency bands centered at 90 and 150 GHz, with 180 pixels at 90 GHz and 588 pixels at 150 GHz. The SPTpol design has several features designed to control polarization systematics, including: single-moded feedhorns with low cross-polarization, bolometer pairs well-matched to difference atmospheric signals, an improved ground shield design based on far-sidelobe measurements of the SPT, and a small beam to reduce temperature to polarization leakage. We present an overview of the SPTpol instrument design, project status, and science projections., 18 pages, 6 figures

Published

2012

5. Frequency selective bolometer development at Argonne National Laboratory

Author

John E. Pearson, Jeff McMahon, John E. Carlstrom, Thushara Perera, Volodymyr Yefremenko, S. S. Meyer, C. L. Chang, Valentyn Novosad, Ralu Divan, Daniel W. Logan, Gensheng Wang, Grant W. Wilson, T. Downes, and A. Datesman

Subjects

Physics, Fabrication, Silicon, business.industry, Bolometer, chemistry.chemical_element, Particle detector, law.invention, chemistry.chemical_compound, Optics, Silicon nitride, chemistry, law, Extremely high frequency, Crystalline silicon, Transition edge sensor, business

Abstract

We discuss the development, at Argonne National Laboratory, of a four-pixel camera suitable for photometry of distant dusty galaxies located by Spitzer and SCUBA, and for study of other millimeter-wave sources such as ultra-luminous infrared galaxies, the Sunyaev-Zeldovich (SZ) effect in clusters, and galactic dust. Utilizing Frequency Selective Bolometers (FSBs) with superconducting Transition-Edge Sensors (TESs), each of the camera's four pixels is sensitive to four colors, with frequency bands centered approximately at 150, 220, 270, and 360 GHz. The current generation of these devices utilizes proximity effect superconducting bilayers of Mo/Au or Ti/Au for TESs, along with frequency selective circuitry on membranes of silicon nitride 1 cm across and 1 micron thick. The operational properties of these devices are determined by this circuitry, along with thermal control structures etched into the membranes. These etched structures do not perforate the membrane, so that the device is both comparatively robust mechanically and carefully tailored in terms of its thermal transport properties. In this paper, we report on development of the superconducting bilayer TES technology and characterization of the FSB stacks. This includes the use of new materials, the design and testing of thermal control structures, the introduction of desirable thermal properties using buried layers of crystalline silicon underneath the membrane, detector stability control, and optical and thermal test results. The scientific motivation, FSB design, FSB fabrication, and measurement results are discussed.

Published

2008

6. Kilopixel backshort-under-grid arrays for the Primordial Inflation Polarization Explorer

Author

Jhabvala, Christine A., additional, Benford, Dominic J., additional, Brekosky, Regis P., additional, Chang, Meng-Ping, additional, Costen, Nicholas P., additional, Datesman, Aaron M., additional, Hilton, Gene C., additional, Irwin, Kent D., additional, Kogut, Alan J., additional, Lazear, Justin, additional, Leong, Edward S., additional, Maher, Stephen F., additional, Miller, Timothy M., additional, Moseley, S. H., additional, Sharp, Elmer H., additional, Staguhn, Johannes G., additional, and Wollack, Edward J., additional

Published

2014

7. Feedhorn-coupled TES polarimeter camera modules at 150 GHz for CMB polarization measurements with SPTpol

Author

Henning, J. W., primary, Ade, P., additional, Aird, K. A., additional, Austermann, J. E., additional, Beall, J. A., additional, Becker, D., additional, Benson, B. A., additional, Bleem, L. E., additional, Britton, J., additional, Carlstrom, J. E., additional, Chang, C. L., additional, Cho, H.-M., additional, Crawford, T. M., additional, Crites, A. T., additional, Datesman, A., additional, de Haan, T., additional, Dobbs, M A., additional, Everett, W., additional, Ewall-Wice, A., additional, George, E. M., additional, Halverson, N. W., additional, Harrington, N., additional, Hilton, G. C., additional, Holzapfel, W. L., additional, Hubmayr, J., additional, Irwin, K. D., additional, Karfunkle, M., additional, Keisler, R., additional, Kennedy, J., additional, Lee, A. T., additional, Leitch, E., additional, Li, D., additional, Lueker, M., additional, Marrone, D. P., additional, McMahon, J. J., additional, Mehl, J., additional, Meyer, S. S., additional, Montgomery, J., additional, Montroy, T. E., additional, Nagy, J., additional, Natoli, T., additional, Nibarger, J. P., additional, Niemack, M. D., additional, Novosad, V., additional, Padin, S., additional, Pryke, C., additional, Reichardt, C. L., additional, Ruhl, J. E., additional, Saliwanchik, B. R., additional, Sayre, J. T., additional, Schaffer, K. K., additional, Shirokoff, E., additional, Story, K., additional, Tucker, C., additional, Vanderlinde, K., additional, Vieira, J. D., additional, Wang, G., additional, Williamson, R., additional, Yefremenko, V., additional, Yoon, K. W., additional, and Young, E., additional

Published

2012

8. Design and characterization of 90 GHz feedhorn-coupled TES polarimeter pixels in the SPTPol camera

Author

Sayre, J. T., primary, Ade, P., additional, Aird, K. A., additional, Austermann, J. E., additional, Beall, J. A., additional, Becker, D., additional, Benson, B. A., additional, Bleem, L. E., additional, Britton, J., additional, Carlstrom, J. E., additional, Chang, C. L., additional, Cho, H.-M., additional, Crawford, T. M., additional, Crites, A. T., additional, Datesman, A., additional, de Haan, T., additional, Dobbs, M. A., additional, Everett, W., additional, Ewall-Wice, A., additional, George, E. M., additional, Halverson, N. W., additional, Harrington, N., additional, Henning, J. W., additional, Hilton, G. C., additional, Holzapfel, W. L., additional, Hubmayr, J., additional, Irwin, K. D., additional, Karfunkle, M., additional, Keisler, R., additional, Kennedy, J., additional, Lee, A. T., additional, Leitch, E., additional, Li, D., additional, Lueker, M., additional, Marrone, D. P., additional, McMahon, J. J., additional, Mehl, J., additional, Meyer, S. S., additional, Montgomery, J., additional, Montroy, T. E., additional, Nagy, J., additional, Natoli, T., additional, Nibarger, J. P., additional, Niemack, M. D., additional, Novosad, V., additional, Padin, S., additional, Pryke, C., additional, Reichardt, C. L., additional, Ruhl, J. E., additional, Saliwanchik, B. R., additional, Schaffer, K. K., additional, Shirokoff, E., additional, Story, K., additional, Tucker, C., additional, Vanderlinde, K., additional, Vieira, J. D., additional, Wang, G., additional, Williamson, R., additional, Yefremenko, V., additional, Yoon, K. W., additional, and Young, E., additional

Published

2012

9. SPTpol: an instrument for CMB polarization measurements with the South Pole Telescope

Author

Austermann, J. E., primary, Aird, K. A., additional, Beall, J. A., additional, Becker, D., additional, Bender, A., additional, Benson, B. A., additional, Bleem, L. E., additional, Britton, J., additional, Carlstrom, J. E., additional, Chang, C. L., additional, Chiang, H. C., additional, Cho, H.-M., additional, Crawford, T. M., additional, Crites, A. T., additional, Datesman, A., additional, de Haan, T., additional, Dobbs, M. A., additional, George, E. M., additional, Halverson, N. W., additional, Harrington, N., additional, Henning, J. W., additional, Hilton, G. C., additional, Holder, G. P., additional, Holzapfel, W. L., additional, Hoover, S., additional, Huang, N., additional, Hubmayr, J., additional, Irwin, K. D., additional, Keisler, R., additional, Kennedy, J., additional, Knox, L., additional, Lee, A. T., additional, Leitch, E., additional, Li, D., additional, Lueker, M., additional, Marrone, D. P., additional, McMahon, J. J., additional, Mehl, J., additional, Meyer, S. S., additional, Montroy, T. E., additional, Natoli, T., additional, Nibarger, J. P., additional, Niemack, M. D., additional, Novosad, V., additional, Padin, S., additional, Pryke, C., additional, Reichardt, C. L., additional, Ruhl, J. E., additional, Saliwanchik, B. R., additional, Sayre, J. T., additional, Schaffer, K. K., additional, Shirokoff, E., additional, Stark, A. A., additional, Story, K., additional, Vanderlinde, K., additional, Vieira, J. D., additional, Wang, G., additional, Williamson, R., additional, Yefremenko, V., additional, Yoon, K. W., additional, and Zahn, O., additional

Published

2012

10. Performance and on-sky optical characterization of the SPTpol instrument

Author

George, E. M., primary, Ade, P., additional, Aird, K. A., additional, Austermann, J. E., additional, Beall, J. A., additional, Becker, D., additional, Bender, A., additional, Benson, B. A., additional, Bleem, L. E., additional, Britton, J., additional, Carlstrom, J. E., additional, Chang, C. L., additional, Chiang, H. C., additional, Cho, H.-M., additional, Crawford, T. M., additional, Crites, A. T., additional, Datesman, A., additional, de Haan, T., additional, Dobbs, M. A., additional, Everett, W., additional, Ewall-Wice, A., additional, Halverson, N. W., additional, Harrington, N., additional, Henning, J. W., additional, Hilton, G. C., additional, Holzapfel, W. L., additional, Hoover, S., additional, Huang, N., additional, Hubmayr, J., additional, Irwin, K. D., additional, Karfunkle, M., additional, Keisler, R., additional, Kennedy, J., additional, Lee, A. T., additional, Leitch, E., additional, Li, D., additional, Lueker, M., additional, Marrone, D. P., additional, McMahon, J. J., additional, Mehl, J., additional, Meyer, S. S., additional, Montgomery, J., additional, Montroy, T. E., additional, Nagy, J., additional, Natoli, T., additional, Nibarger, J. P., additional, Niemack, M. D., additional, Novosad, V., additional, Padin, S., additional, Pryke, C., additional, Reichardt, C. L., additional, Ruhl, J. E., additional, Saliwanchik, B. R., additional, Sayre, J. T., additional, Schaffer, K. K., additional, Shirokoff, E., additional, Story, K., additional, Tucker, C., additional, Vanderlinde, K., additional, Vieira, J. D., additional, Wang, G., additional, Williamson, R., additional, Yefremenko, V., additional, Yoon, K. W., additional, and Young, E., additional

Published

2012

11. South Pole Telescope software systems: control, monitoring, and data acquisition

Author

Story, K., primary, Leitch, E., additional, Ade, P., additional, Aird, K. A., additional, Austermann, J. E., additional, Beall, J. A., additional, Becker, D., additional, Bender, A. N., additional, Benson, B. A., additional, Bleem, L. E., additional, Britton, J., additional, Carlstrom, J. E., additional, Chang, C. L., additional, Chiang, H. C., additional, Cho, H-M., additional, Crawford, T. M., additional, Crites, A. T., additional, Datesman, A., additional, de Haan, T., additional, Dobbs, M. A., additional, Everett, W., additional, Ewall-Wice, A., additional, George, E. M., additional, Halverson, N. W., additional, Harrington, N., additional, Henning, J. W., additional, Hilton, G. C., additional, Holzapfel, W. L., additional, Hoover, S., additional, Huang, N., additional, Hubmayr, J., additional, Irwin, K. D., additional, Karfunkle, M., additional, Keisler, R., additional, Kennedy, J., additional, Lee, A. T., additional, Li, D., additional, Lueker, M., additional, Marrone, D. P., additional, McMahon, J. J., additional, Mehl, J., additional, Meyer, S. S., additional, Montgomery, J., additional, Montroy, T. E., additional, Nagy, J., additional, Natoli, T., additional, Nibarger, J. P., additional, Niemack, M. D., additional, Novosad, V., additional, Padin, S., additional, Pryke, C., additional, Reichardt, C. L., additional, Ruhl, J. E., additional, Saliwanchik, B. R., additional, Sayre, J. T., additional, Schaffer, K. K., additional, Shirokoff, E., additional, Smecher, G., additional, Stalder, B., additional, Tucker, C., additional, Vanderlinde, K., additional, Vieira, J. D., additional, Wang, G., additional, Williamson, R., additional, Yefremenko, V., additional, Yoon, K. W., additional, and Young, E., additional

Published

2012

12. Frequency selective bolometer development at Argonne National Laboratory

Author

Datesman, Aaron, primary, Pearson, John, additional, Wang, Gensheng, additional, Yefremenko, Volodymyr, additional, Divan, Ralu, additional, Downes, Thomas, additional, Chang, Clarence, additional, McMahon, Jeff, additional, Meyer, Stephan, additional, Carlstrom, John, additional, Logan, Daniel, additional, Perera, Thushara, additional, Wilson, Grant, additional, and Novosad, Valentyn, additional

Published

2008