Your search keyword '"McBreen, S"' showing total 6 results

1. Ground-based calibration and characterization of the Fermi gamma-ray burst monitor detectors

Author

Bissaldi, E., primary, von Kienlin, A., additional, Lichti, G., additional, Steinle, H., additional, Bhat, P. N., additional, Briggs, M. S., additional, Fishman, G. J., additional, Hoover, A. S., additional, Kippen, R. M., additional, Krumrey, M., additional, Gerlach, M., additional, Connaughton, V., additional, Diehl, R., additional, Greiner, J., additional, van der Horst, A. J., additional, Kouveliotou, C., additional, McBreen, S., additional, Meegan, C. A., additional, Paciesas, W. S., additional, Preece, R. D., additional, and Wilson-Hodge, C. A., additional

Published

2009

2. Gamma-ray burst investigation via polarimetry and spectroscopy (GRIPS)

Author

Greiner, J., primary, Iyudin, A., additional, Kanbach, G., additional, Zoglauer, A., additional, Diehl, R., additional, Ryde, F., additional, Hartmann, D., additional, Kienlin, A. v., additional, McBreen, S., additional, Ajello, M., additional, Bagoly, Z., additional, Balasz, L. G., additional, Barbiellini, G., additional, Bellazini, R., additional, Bezrukov, L., additional, Bisikalo, D. V., additional, Bisnovaty-Kogan, G., additional, Boggs, S., additional, Bykov, A., additional, Cherepashuk, A. M., additional, Chernenko, A., additional, Collmar, W., additional, DiCocco, G., additional, Dröge, W., additional, Gierlik, M., additional, Hanlon, L., additional, Horvath, I., additional, Hudec, R., additional, Kiener, J., additional, Labanti, C., additional, Langer, N., additional, Larsson, S., additional, Lichti, G., additional, Lipunov, V. M., additional, Lubsandorgiev, B. K., additional, Majczyna, A., additional, Mannheim, K., additional, Marcinkowski, R., additional, Marisaldi, M., additional, McBreen, B., additional, Meszaros, A., additional, Orlando, E., additional, Panasyuk, M. I., additional, Pearce, M., additional, Pian, E., additional, Poleschuk, R. V., additional, Pollo, A., additional, Pozanenko, A., additional, Savaglio, S., additional, Shustov, B., additional, Strong, A., additional, Svertilov, S., additional, Tatischeff, V., additional, Uvarov, J., additional, Varshalovich, D. A., additional, Wunderer, C. B., additional, Wrochna, G., additional, Zabrodskij, A. G., additional, and Zeleny, L. M., additional

Published

2008

3. Gamma-ray burst investigation via polarimetry and spectroscopy (GRIPS).

Author

Greiner, J., Iyudin, A., Kanbach, G., Zoglauer, A., Diehl, R., Ryde, F., Hartmann, D., Kienlin, A. v., McBreen, S., Ajello, M., Bagoly, Z., Balasz, L. G., Barbiellini, G., Bellazini, R., Bezrukov, L., Bisikalo, D. V., Bisnovaty-Kogan, G., Boggs, S., Bykov, A., and Cherepashuk, A. M.

Subjects

GAMMA ray bursts, GAMMA ray spectrometry, POLARIMETRY, ASTRONOMICAL spectroscopy, SUPERNOVAE, GALAXIES, COMPACT objects (Astronomy), SUPERGIANT stars, NOVAE (Astronomy), RADIOACTIVE decay

Abstract

The primary scientific goal of the GRIPS mission is to revolutionize our understanding of the early universe using γ-ray bursts. We propose a new generation gamma-ray observatory capable of unprecedented spectroscopy over a wide range of γ-ray energies (200 keV–50 MeV) and of polarimetry (200–1000 keV). The γ-ray sensitivity to nuclear absorption features enables the measurement of column densities as high as 1028cm − 2. Secondary goals achievable by this mission include direct measurements of all types of supernova interiors through γ-rays from radioactive decays, nuclear astrophysics with massive stars and novae, and studies of particle acceleration near compact stars, interstellar shocks, and clusters of galaxies. [ABSTRACT FROM AUTHOR]

Published

2009

4. A compact instrument for gamma-ray burst detection on a CubeSat platform II: Detailed design, assembly and validation.

Author

Murphy D, Ulyanov A, McBreen S, Mangan J, Dunwoody R, Doyle M, O'Toole C, Thompson J, Reilly J, Walsh S, Shortt B, Martin-Carrillo A, and Hanlon L

Abstract

The Gamma-ray Module, GMOD, is a miniaturised novel gamma-ray detector which will be the primary scientific payload on the Educational Irish Research Satellite (EIRSAT-1) 2U CubeSat mission. GMOD comprises a compact (25 mm × 25 mm × 40 mm) cerium bromide scintillator coupled to a tiled array of 4 × 4 silicon photomultipliers, with front-end readout provided by the IDE3380 SIPHRA. This paper presents the detailed GMOD design and the accommodation of the instrument within the restrictive CubeSat form factor. The electronic and mechanical interfaces are compatible with many off-the-shelf CubeSat systems and structures. The energy response of the GMOD engineering qualification model has been determined using radioactive sources, and an energy resolution of 5.4% at 662 keV has been measured. EIRSAT-1 will perform on-board processing of GMOD data. Trigger results, including light-curves and spectra, will be incorporated into the spacecraft beacon and transmitted continuously. Inexpensive hardware can be used to decode the beacon signal, making the data accessible to a wide community. GMOD will have scientific capability for the detection of gamma-ray bursts, in addition to the educational and technology demonstration goals of the EIRSAT-1 mission. The detailed design and measurements to date demonstrate the capability of GMOD in low Earth orbit, the scalability of the design for larger CubeSats and as an element of future large gamma-ray missions., Competing Interests: Conflicts of interestThe authors declare no conflict of interest., (© The Author(s) 2022.)

Published

2022

5. Balloon flight test of a CeBr 3 detector with silicon photomultiplier readout.

Author

Murphy D, Mangan J, Ulyanov A, Walsh S, Dunwoody R, Hanlon L, Shortt B, and McBreen S

Abstract

Recent advances in silicon photomultiplier (SiPM) technology and new scintillator materials allow for the creation of compact high-performance gamma-ray detectors which can be deployed on small low-cost satellites. A small number of such satellites can provide full sky coverage and complement, or in some cases replace the existing gamma-ray missions in detection of transient gamma-ray events. The aim of this study is to test gamma-ray detection using a novel commercially available CeBr 3 scintillator combined with SiPM readout in a near-space environment and inform further technology development for a future space mission. A prototype gamma-ray detector was built using a CeBr 3 scintillator and an array of 16 J-Series SiPMs by ON Semiconductor. SiPM readout was performed using SIPHRA, a radiation-tolerant low-power integrated circuit developed by IDEAS. The detector was flown as a piggyback payload on the Advanced Scintillator Compton Telescope balloon flight from Columbia Scientific Balloon Facility. The payload included the detector, a Raspberry Pi on-board computer, a custom power supply board, temperature and pressure sensors, a Global Navigation Satellite System receiver and a satellite modem. The balloon delivered the detector to 37 km altitude where its detection capabilities and readout were tested in the radiation-intense near-space environment. The detector demonstrated continuous operation during the 8-hour flight and after the landing. It performed spectral measurements in an energy range of 100 keV to 8 MeV and observed the 511 keV gamma-ray line arising from positron annihilation in the atmosphere with full width half maximum of 6.8%. During ascent and descent, the detector count rate peaked at an altitude of 16 km corresponding to the point of maximum radiation intensity in the atmosphere. Despite several engineering issues discovered after the flight test, the results of this study confirm the feasibility of using CeBr 3 scintillator, SiPMs, and SIPHRA in future space missions., (© The Author(s) 2021.)

Published

2021

6. A compact instrument for gamma-ray burst detection on a CubeSat platform I: Design drivers and expected performance.

Author

Murphy D, Ulyanov A, McBreen S, Doyle M, Dunwoody R, Mangan J, Thompson J, Shortt B, Martin-Carrillo A, and Hanlon L

Abstract

The Educational Irish Research Satellite 1 (EIRSAT-1) is a 2U CubeSat being developed under ESA's Fly Your Satellite! programme. The project has many aspects, which are primarily educational, but also include space qualification of new detector technologies for gamma-ray astronomy and the detection of gamma-ray bursts (GRBs). The Gamma-ray Module (GMOD), the main mission payload, is a small gamma-ray spectrometer comprising a 25 mm × 25 mm × 40 mm cerium bromide scintillator coupled to an array of 16 silicon photomultipliers. The readout is provided by IDE3380 (SIPHRA), a low-power and radiation tolerant readout ASIC. GMOD will detect gamma-rays and measure their energies in a range from tens of keV to a few MeV. Monte Carlo simulations were performed using the Medium Energy Gamma-ray Astronomy Library to evaluate GMOD's capability for the detection of GRBs in low Earth orbit. The simulations used a detailed mass model of the full spacecraft derived from a very high-fidelity 3D CAD model. The sky-average effective area of GMOD on board EIRSAT-1 was found to be 10 cm 2 at 120 keV. The instrument is expected to detect between 11 and 14 GRBs, at a significance greater than 10 σ (and up to 32 at 5 σ ), during a nominal one-year mission. The shape of the scintillator in GMOD results in omni-directional sensitivity which allows for a nearly all-sky field of view., (© The Author(s) 2021.)

Published

2021