Your search keyword '"Christopher M. Bancroft"' showing total 19 results

1. Initial results from the Advanced Scintillator Compton Telescope (ASCOT) Balloon Flight

Author

Tejaswita Sharma, James M. Ryan, Mark L. McConnell, Peter F. Bloser, Jason S. Legere, Christopher M. Bancroft, and Colin Frost

Subjects

Physics, business.industry, Position resolution, Astrophysics::High Energy Astrophysical Phenomena, Compton telescope, Conjunction (astronomy), Astrophysics::Instrumentation and Methods for Astrophysics, 02 engineering and technology, Scintillator, 021001 nanoscience & nanotechnology, 01 natural sciences, 010309 optics, Optics, Crab Nebula, Silicon photomultiplier, Cerium bromide, 0103 physical sciences, Palestine, 0210 nano-technology, business

Abstract

A medium-energy gamma-ray Compton telescope called the Advanced Scintillator Compton Telescope (ASCOT) was designed to address the existing need for observations in the gamma-ray energy range of 0.4 - 20 MeV. Built on the legacy of COMPTEL instrument onboard NASA’s CGRO, ASCOT uses commercially available high-performance scintillators, such as Cerium Bromide (CeBr 3 ) and p-terphenyl in conjunction with Silicon Photomultipliers (SiPM) as compact readout devices to improve the instrument response. ASCOT also makes use of the Time-of-Flight background rejection technique along with the hardware advancement, an important tool for effective imaging in this energy range. ASCOT was developed with the goal of imaging the Crab Nebula at MeV energies during a high-altitude balloon flight. The instrument was successfully launched by NASA from Palestine (TX) on 5th July 2018. It operated stably and observed the Crab for ~5 hours from an altitude of 120,000 ft. Based on pre-flight calibrations and simulations results we expect a ~4.5 sigma detection of the Crab in the 0.2 - 2 MeV band. We present here the calibrated flight data along with preliminary results. The findings from ASCOT will demonstrate an improvement in the energy, timing, and position resolution using this advanced technology.

Published

2019

2. Balloon flight test of a Compton telescope based on scintillators with silicon photomultiplier readouts

Author

James M. Ryan, Peter F. Bloser, Mark L. McConnell, Christopher M. Bancroft, and Jason S. Legere

Subjects

Nuclear and High Energy Physics, Physics - Instrumentation and Detectors, Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, Compton telescope, FOS: Physical sciences, Field of view, Scintillator, 01 natural sciences, 010309 optics, Silicon photomultiplier, Optics, 0103 physical sciences, Wide dynamic range, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics, Instrumentation, Physics, business.industry, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, Instrumentation and Detectors (physics.ins-det), Flight test, Astrophysics - Instrumentation and Methods for Astrophysics, business

Abstract

We present the results of the first high-altitude balloon flight test of a concept for an advanced Compton telescope making use of modern scintillator materials with silicon photomultiplier (SiPM) readouts. There is a need in the fields of high-energy astronomy and solar physics for new medium-energy gamma-ray (~0.4 - 10 MeV) detectors capable of making sensitive observations. A fast scintillator- based Compton telescope with SiPM readouts is a promising solution to this instrumentation challenge, since the fast response of the scintillators permits the rejection of background via time-of-flight (ToF) discrimination. The Solar Compton Telescope (SolCompT) prototype was designed to demonstrate stable performance of this technology under balloon-flight conditions. The SolCompT instrument was a simple two-element Compton telescope, consisting of an approximately one-inch cylindrical stilbene crystal for a scattering detector and a one-inch cubic LaBr3:Ce crystal for a calorimeter detector. Both scintillator detectors were read out by 2 x 2 arrays of Hamamatsu S11828-3344 MPPC devices. Custom front-end electronics provided optimum signal rise time and linearity, and custom power supplies automatically adjusted the SiPM bias voltage to compensate for temperature-induced gain variations. A tagged calibration source, consisting of ~240 nCi of Co-60 embedded in plastic scintillator, was placed in the field of view and provided a known source of gamma rays to measure in flight. The SolCompT balloon payload was launched on 24 August 2014 from Fort Sumner, NM, and spent ~3.75 hours at a float altitude of ~123,000 feet. The instrument performed well throughout the flight. After correcting for small (~10%) residual gain variations, we measured an in-flight ToF resolution of ~760 ps (FWHM). Advanced scintillators with SiPM readouts continue to show great promise for future gamma-ray instruments., Comment: 39 pages, 25 figures, to appear in NIM-A

Published

2016

3. The Advanced Scintillator Compton Telescope (ASCOT) balloon payload

Author

Alex M. Wright, James M. Ryan, Mark L. McConnell, Christopher M. Bancroft, Jason S. Legere, Tejaswita Sharma, and Peter F. Bloser

Subjects

03 medical and health sciences, 0302 clinical medicine, 010308 nuclear & particles physics, 0103 physical sciences, 01 natural sciences, 030218 nuclear medicine & medical imaging

Published

2018

4. Preparations for the Advanced Scintillator Compton Telescope (ASCOT) balloon flight

Author

Peter F. Bloser, Alex M. Wright, Christopher M. Bancroft, James M. Ryan, Tejaswita Sharma, Mark L. McConnell, and Jason S. Legere

Subjects

Physics, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Compton telescope, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, Scintillator, Silicon photomultiplier, Optics, Crab Nebula, Calibration, business, Sensitivity (electronics)

Abstract

We describe our ongoing work to develop a new medium-energy gamma-ray Compton telescope using advanced scintillator materials combined with silicon photomultiplier readouts and fly it on a scientific balloon. There is a need in high-energy astronomy for a medium-energy gamma-ray mission covering the energy range from approximately 0.4 - 20 MeV to follow the success of the COMPTEL instrument on CGRO. We believe that directly building on the legacy of COMPTEL, using relatively robust, low-cost, off-the-shelf technologies, is the most promising path for such a mission. Fortunately, high-performance scintillators, such as Cerium Bromide (CeBr3) and p-terphenyl, and compact readout devices, such as silicon photomultipliers (SiPMs), are already commercially available and capable of meeting this need. We are now constructing an Advanced Scintillator Compton Telescope (ASCOT) with SiPM readout, with the goal of imaging the Crab Nebula at MeV energies from a high-altitude balloon flight. We expect a ~4-sigma detection at ~1 MeV in a single transit. We present calibration results of the detector modules, and updated simulations of the balloon instrument sensitivity. If successful, this project will demonstrate that the energy, timing, and position resolution of this technology are sufficient to achieve an order of magnitude improvement in sensitivity in the medium-energy gamma-ray band, were it to be applied to a ~1 cubic meter instrument on a long-duration balloon or Explorer platform.

Published

2017

5. Testing and simulation of silicon photomultiplier readouts for scintillators in high-energy astronomy and solar physics

Author

Jason S. Legere, Peter F. Bloser, Christopher M. Bancroft, Camden Ertley, Jonathan Wurtz, Mark L. McConnell, Luke F. Jablonski, and James M. Ryan

Subjects

Physics, Nuclear and High Energy Physics, Photomultiplier, Scintillation, Spectrometer, Physics::Instrumentation and Detectors, business.industry, Detector, Scintillator, Solar physics, Optics, Silicon photomultiplier, business, Instrumentation, Radiation hardening

Abstract

Space-based gamma-ray detectors for high-energy astronomy and solar physics face severe constraints on mass, volume, and power, and must endure harsh launch conditions and operating environments. Historically, such instruments have usually been based on scintillator materials due to their relatively low cost, inherent ruggedness, high stopping power, and radiation hardness. New scintillator materials, such as LaBr 3 :Ce, feature improved energy and timing performance, making them attractive for future astronomy and solar physics space missions in an era of tightly constrained budgets. Despite this promise, the use of scintillators in space remains constrained by the volume, mass, power, and fragility of the associated light readout device, typically a vacuum photomultiplier tube (PMT). In recent years, silicon photomultipliers (SiPMs) have emerged as promising alternative light readout devices that offer gains and quantum efficiencies similar to those of PMTs, but with greatly reduced mass and volume, high ruggedness, low voltage requirements, and no sensitivity to magnetic fields. In order for SiPMs to replace PMTs in space-based instruments, however, it must be shown that they can provide comparable performance, and that their inherent temperature sensitivity can be corrected for. To this end, we have performed extensive testing and modeling of a small gamma-ray spectrometer composed of a 6 mm×6 mm SiPM coupled to a 6 mm×6 mm ×10 mm LaBr 3 :Ce crystal. A custom readout board monitors the temperature and adjusts the bias voltage to compensate for gain variations. We record an energy resolution of 5.7% (FWHM) at 662 keV at room temperature. We have also performed simulations of the scintillation process and optical light collection using Geant4, and of the SiPM response using the GosSiP package. The simulated energy resolution is in good agreement with the data from 22 keV to 662 keV. Above ~1 MeV, however, the measured energy resolution is systematically worse than the simulations. This discrepancy is likely due to the high input impedance of the readout board front-end electronics, which introduces a non-linear saturation effect in the SiPM for large light pulses. Analysis of the simulations indicates several additional steps that must be taken to optimize the energy resolution of SiPM-based scintillator detectors.

Published

2014

6. The Advanced Scintillator Compton Telescope (ASCOT) balloon project

Author

Peter F. Bloser, Alex M. Wright, Christopher M. Bancroft, Mark L. McConnell, James M. Ryan, Jason S. Legere, and Tejaswita Sharma

Subjects

Physics, Calorimeter (particle physics), Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Instrumentation, Compton telescope, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Scintillator, 01 natural sciences, law.invention, Telescope, Silicon photomultiplier, Optics, law, 0103 physical sciences, Calibration, business, 010303 astronomy & astrophysics

Abstract

We describe a project to develop new medium-energy gamma-ray instrumentation by constructing and flying a balloon-borne Compton telescope using advanced scintillator materials combined with silicon photomultiplier readouts. There is a need in high-energy astronomy for a medium-energy gamma-ray mission covering the energy range from approximately 0.4 - 20 MeV to follow the success of the COMPTEL instrument on CGRO. We believe that directly building on the legacy of COMPTEL, using relatively robust, low-cost, off-the-shelf technologies, is the most promising path for such a mission. Fortunately, high-performance scintillators, such as Lanthanum Bromide (LaBr3), Cerium Bromide (CeBr3), and p-terphenyl, and compact readout devices, such as silicon photomultipliers (SiPMs), are already commercially available and capable of meeting this need. We have conducted two balloon flights of prototype instruments to test these technologies. The first, in 2011, demonstrated that a Compton telescope consisting of an liquid organic scintillator scattering layer and a LaBr3 calorimeter effectively rejects background under balloon-flight conditions, using time-of-flight (ToF) discrimination. The second, in 2014, showed that a telescope using an organic stilbene crystal scattering element and a LaBr3 calorimeter with SiPM readouts can achieve similar ToF performance. We are now constructing a much larger balloon instrument, an Advanced Scintillator Compton Telescope (ASCOT) with SiPM readout, with the goal of imaging the Crab Nebula at MeV energies in a one-day flight. We expect a ~4σ detection up to ~1 MeV in a single transit. We present calibration results of the first detector modules, and updated simulations of the balloon instrument sensitivity. If successful, this project will demonstrate that the energy, timing, and position resolution of this technology are sufficient to achieve an order of magnitude improvement in sensitivity in the mediumenergy gamma-ray band, were it to be applied to a ~1 cubic meter instrument on a long-duration balloon or Explorer platform.

Published

2016

7. The advanced scintillator Compton telescope (ASCOT) balloon project

Author

Christopher M. Bancroft, Tessa M. Gorte, James M. Ryan, Jason S. Legere, Mark L. McConnell, Colin Frost, Peter F. Bloser, and Alex M. Wright

Subjects

Physics, Photomultiplier, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Instrumentation, Compton telescope, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, Scintillator, Silicon photomultiplier, Crab Nebula, Optics, business

Abstract

We describe a project to develop new medium-energy gamma-ray instrumentation by constructing and flying a balloon-borne Compton telescope using advanced scintillator materials combined with silicon photomultiplier readouts. There is a need in high-energy astronomy for a medium-energy gamma-ray mission covering the energy range from approximately 0.4–20 MeV to follow the success of the COMPTEL instrument on CGRO. We believe that directly building on the legacy of COMPTEL, using relatively robust, low-cost, off-the-shelf technologies, is the most promising path for such a mission. Fortunately, high-performance scintillators, such as Lanthanum Bromide (LaBr 3 ), Cerium Bromide (CeBr 3 ), and p-terphenyl, and compact readout devices, such as silicon photomultipliers (SiPMs), are already commercially available and capable of meeting this need. We have conducted two balloon flights of prototype instruments to test these technologies. We have now begun work on a much larger balloon instrument, an Advanced Scintillator Compton Telescope (ASCOT) with SiPM readout, with the goal of imaging the Crab Nebula at MeV energies in a one-day flight. We expect a ∼4σ detection at ∼1 MeV in a single transit. If successful, this will demonstrate that the energy, timing, and position resolution of this technology are sufficient to achieve an order of magnitude improvement in sensitivity in the medium-energy gamma-ray band, were it to be applied to a ∼1 cubic meter instrument on a long-duration balloon or Explorer platform.

Published

2015

8. Scintillator gamma-ray detectors with silicon photomultiplier readouts for high-energy astronomy

Author

Peter F. Bloser, Christopher M. Bancroft, Mark L. McConnell, James M. Ryan, Nathan A. Schwadron, and Jason S. Legere

Subjects

Physics, Photomultiplier, Physics::Instrumentation and Detectors, business.industry, High-energy astronomy, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Scintillator, Silicon photomultiplier, Optics, Gamma ray detectors, Lanthanum bromide, Gamma spectroscopy, business

Abstract

Space-based gamma-ray detectors for high-energy astronomy face strict constraints of mass, volume, and power, and must endure harsh operating environments. Scintillator materials have a long history of successful operation under these conditions, and new materials offer greatly improved performance in terms of efficiency, time response, and energy resolution. The use of scintillators in space remains constrained, however, by the mass, volume, and fragility of the associated light readout device, typically a vacuum photomultiplier tube (PMT). Recently developed silicon photomultipliers (SiPMs) offer gains and efficiencies similar to those of PMTs, but with greatly reduced mass and volume, high ruggedness, and no high-voltage requirements. We have therefore been investigating the use of SiPM readouts for scintillator gamma-ray detectors, with an emphasis on their suitability for space- and balloonbased instruments for high-energy astronomy. We present our most recent results, including spectroscopy measurements for lanthanum bromide scintillators with SiPM readouts, and pulse-shape discrimination using organic scintillators with SiPM readouts. We also describe potential applications of SiPM readouts to specific highenergy astronomy instrument concepts.

Published

2013

9. Balloon flight results of a FAst compton telescope (FACTEL)

Author

Mark L. McConnell, R. Marc Kippen, Shawn Tornga, Manuel Julien, Jason S. Legere, Christopher M. Bancroft, Peter F. Bloser, and James M. Ryan

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Compton telescope, Monte Carlo method, Antenna aperture, Astrophysics::Instrumentation and Methods for Astrophysics, Scintillator, Balloon, Time of flight, Optics, Neutron, business, Background radiation

Abstract

Current medium energy gamma-ray astronomy is limited by the intense atmospheric or local background radiation degrading the sensitivity of instruments. Compton Telescopes' background rejection capabilities can be significantly improved with no loss of effective area by narrowing as much as possible the event acceptance Time of Flight (ToF) window by using fast scintillators materials such as LaBr3. We present the balloon test flight results of the FAst Compton TELescope (FACTEL) prototype we built using LaBr3 scintillators, along with other techniques to reduce the neutron induced background. This 26 hour flight from NASA's Columbia Scientific Balloon Facility at Fort Sumner, New Mexico, permitted us to evaluate the background rejection capabilities offered by our 1.2 ns ToF window compared to COMPTEL's 4 ns. We also report laboratory and Monte Carlo simulations results. We use these results to make a preliminary evaluation of the performance of a larger future instrument based on similar principles.

Published

2012

10. Balloon-flight test of a lanthanum bromide gamma-ray detector with silicon photomultiplier readout

Author

Luke F. Jablonski, Jonathan Wurtz, Peter F. Bloser, Christopher M. Bancroft, James M. Ryan, Mark L. McConnell, and Jason S. Legere

Subjects

Physics, Photomultiplier, Scintillation, Silicon photomultiplier, Optics, Spectrometer, Physics::Instrumentation and Detectors, business.industry, Nuclear electronics, Detector, Scintillator, business, Low voltage

Abstract

New scintillator materials have been shown to hold great potential for low-cost, reliable gamma-ray detectors in high-energy astronomy and solar physics. New devices for the detection of scintillation light promise to make scintillator-based instruments even more attractive by reducing mass and power requirements. In particular, silicon photomultipliers (SiPMs) are commercially available that offer gains and quantum efficiencies similar to those of photomultiplier tubes (PMTs), but with greatly reduced mass, high ruggedness, low voltage requirements, and no sensitivity to magnetic fields. SiPMs have by now been shown to perform well as readouts for scintillator gamma-ray detectors in the laboratory. Before they may used in space-based instruments, however, it must be shown that 1) sufficiently large light collecting areas may be fabricated without loss of performance; 2) the variability of the gain with temperature can be compensated for; and 3) that SiPMs are sufficiently robust and radiation hard. We present results from ongoing work to investigate whether SiPMs are appropriate for use in space, including data from the successful flight of a combined LaBr3/SiPM detector on a high-altitude scientific balloon, and the performance of larger gamma-ray spectrometers with improved light collection.

Published

2012

11. An imaging neutron spectrometer

Author

Christopher M. Bancroft, Jane C. Pavlich, Peter F. Bloser, Colin Frost, Mark L. McConnell, Dominique Fourguette, Greg Ritter, Ulisse Bravar, Greg Wassick, James M. Ryan, Richard S. Woolf, Liane Larocque, Joshua R. Wood, and Jason S. Legere

Subjects

Bonner sphere, Physics, Spectrometer, Neutron emission, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Scintillator, Radiation, Nuclear physics, Optics, Neutron detection, Neutron source, Neutron, Nuclear Experiment, business

Abstract

We have developed, fabricated and tested a prototype imaging neutron spectrometer designed for real-time neutron source location and identification. Real-time detection and identification is important for locating materials. These materials, specifically uranium and transuranics, emit neutrons via spontaneous or induced fission. Unlike other forms of radiation (e.g. gamma rays), penetrating neutron emission is very uncommon. The instrument detects these neutrons, constructs images of the emission pattern, and reports the neutron spectrum. The device will be useful for security and proliferation deterrence, as well as for nuclear waste characterization and monitoring. The instrument is optimized for imaging and spectroscopy in the 1–20 MeV range. The detection principle is based upon multiple elastic neutron-proton scatters in organic scintillator. Two detector panel layers are utilized. By measuring the recoil proton and scattered neutron locations and energies, the direction and energy spectrum of the incident neutrons can be determined and discrete and extended sources identified. Event reconstruction yields an image of the source and its location. The hardware is low power, low mass, and rugged. Its modular design allows the user to combine multiple units for increased sensitivity. We will report the results of laboratory testing of the instrument, including exposure to a calibrated Cf-252 source. Instrument parameters include energy and angular resolution, gamma rejection, minimum source identification distances and times, and projected effective area for a fully populated instrument.

Published

2010

12. Preparations for the first balloon flight of the Gamma-Ray Polarimeter Experiment (GRAPE)

Author

Christopher M. Bancroft, Peter F. Bloser, James M. Ryan, Steven P. Longworth, Mark L. McConnell, Taylor Connor, Gerard B. Pape, Colin Frost, and Jason S. Legere

Subjects

Physics, Solar flare, Payload, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, Astronomy, Polarimeter, Polarization (waves), Crab Nebula, Optics, business, Gamma-ray burst

Abstract

We have developed a design for a hard X-ray Compton polarimeter operating in the energy range from 50 to 500 keV, which we refer to as GRAPE (Gamma-Ray Polarimeter Experiment). We are currently preparing a balloon payload for a flight from Ft. Sumner, NM in the fall of 2011. Using a large (16-element) array of detector modules, this payload is being designed to search for polarization from known point sources of radiation, namely the Crab and Cygnus X-1. This first flight will not only provide a scientific demonstration of the GRAPE design (by measuring polarization from the Crab nebula), it will also lay the foundation for subsequent long duration balloon flights that will be designed for studying polarization from gamma-ray bursts and solar flares. Here we shall present data from calibration of the first flight module detectors and review the latest payload design.

Published

2010

13. Silicon photo-multiplier readouts for scintillator-based gamma-ray detectors in space

Author

Mark L. McConnell, Christopher M. Bancroft, Jason S. Legere, James M. Ryan, Peter F. Bloser, and Luke F. Jablonski

Subjects

Physics, Photomultiplier, Optics, Silicon photomultiplier, Spectrometer, Physics::Instrumentation and Detectors, business.industry, High-energy astronomy, Monte Carlo method, Detector, Scintillator, Photonics, business

Abstract

New scintillator materials have been shown to hold great potential for low-cost, reliable gamma-ray detectors in high-energy astronomy and solar physics. Commercially available silicon photo-multipliers (SiPMs) promise to make scintillator-based instruments even more attractive by reducing mass and power requirements. SiPMs have by now been shown to perform well as readouts for scintillator gamma-ray detectors in the laboratory. We present results from ongoing work to investigate whether SiPMs are appropriate for use in space, including the Monte Carlo modeling of the light collection in a small LaBr 3 /SiPM spectrometer scheduled to fly on a high-altitude balloon flight in 2011.

Published

2010

14. A portable neutron spectroscope (NSPECT) for detection, imaging and identification of nuclear material

Author

Dominique Fourguette, Greg Ritter, Ulisse Bravar, Jane C. Pavlich, Richard S. Woolf, Jason S. Legere, Mark L. McConnell, Liane Larocque, Christopher M. Bancroft, Peter F. Bloser, Greg Wassick, Colin Frost, Joshua R. Wood, and James M. Ryan

Subjects

Physics, Spectrometer, Neutron emission, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Radiation, Scintillator, Neutron spectroscopy, Nuclear magnetic resonance, Optics, Neutron source, Neutron detection, Neutron, Nuclear Experiment, business

Abstract

We have developed, fabricated and tested a prototype imaging neutron spectrometer designed for real-time neutron source location and identification. Real-time detection and identification is important for locating materials. These materials, specifically uranium and transuranics, emit neutrons via spontaneous or induced fission. Unlike other forms of radiation (e.g. gamma rays), penetrating neutron emission is very uncommon. The instrument detects these neutrons, constructs images of the emission pattern, and reports the neutron spectrum. The device will be useful for security and proliferation deterrence, as well as for nuclear waste characterization and monitoring. The instrument is optimized for imaging and spectroscopy in the 1-20 MeV range. The detection principle is based upon multiple elastic neutron-proton scatters in organic scintillator. Two detector panel layers are utilized. By measuring the recoil proton and scattered neutron locations and energies, the direction and energy spectrum of the incident neutrons can be determined and discrete and extended sources identified. Event reconstruction yields an image of the source and its location. The hardware is low power, low mass, and rugged. Its modular design allows the user to combine multiple units for increased sensitivity. We will report the results of laboratory testing of the instrument, including exposure to a calibrated Cf-252 source. Instrument parameters include energy and angular resolution, gamma rejection, minimum source identification distances and times, and projected effective area for a fully populated instrument.

Published

2010

15. Plans for the first balloon flight of the gamma-ray polarimeter experiment (GRAPE)

Author

James M. Ryan, Christopher M. Bancroft, Steven P. Longworth, Mark L. McConnell, Taylor Connor, Gerard B. Pape, Peter F. Bloser, Jason S. Legere, and Colin Frost

Subjects

Physics, Photon, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Polarimetry, Gamma ray, Astronomy, Polarimeter, Polarization (waves), Optics, Crab Nebula, business, Gamma-ray burst

Abstract

We have developed a design for a hard X-ray Compton polarimeter operating in the energy range from 50 to 500 keV, which we refer to as GRAPE (Gamma-Ray Polarimeter Experiment). We are currently preparing a balloon payload for a flight from Ft. Sumner, NM in the fall of 2011. Using a large (16-element) array of detector modules, this payload is being designed to search for polarization from known point sources of radiation, namely the Crab and Cygnus X-1. This first flight will not only provide a scientific demonstration of the GRAPE design (by measuring polarization from the Crab nebula), it will also lay the foundation for subsequent long duration balloon flights that will be designed for studying polarization from gamma-ray bursts and solar flares. Here we shall present data from calibration of the first flight module detectors and review the latest payload design.

Published

2010

16. A fast scintillator Compton telescope for medium-energy gamma-ray astronomy

Author

Mark S. Wallace, Mark L. McConnell, R. Marc Kippen, Christopher M. Bancroft, Shawn Tornga, Peter F. Bloser, James M. Ryan, Jason S. Legere, and Manuel Julien

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Compton telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, Gamma-ray astronomy, Scintillator, law.invention, Telescope, Optics, Observatory, law, Nuclear astrophysics, business, Fermi Gamma-ray Space Telescope

Abstract

The field of medium-energy gamma-ray astronomy urgently needs a new mission to build on the success of the COMPTEL instrument on the Compton Gamma Ray Observatory. This mission must achieve sensitivity significantly greater than that of COMPTEL in order to advance the science of relativistic particle accelerators, nuclear astrophysics, and diffuse backgrounds, and bridge the gap between current and future hard X-ray missions and the high-energy Fermi mission. Such an increase in sensitivity can only come about via a dramatic decrease in the instrumental background. We are currently developing a concept for a low-background Compton telescope that employs modern scintillator technology to achieve this increase in sensitivity. Specifically, by employing LaBr 3 scintillators for the calorimeter, one can take advantage of the unique speed and resolving power of this material to improve the instrument sensitivity while simultaneously enhancing its spectroscopic and imaging performance. Also, using deuterated organic scintillator in the scattering detector will reduce internal background from neutron capture. We present calibration results from a laboratory prototype of such an instrument, including time-of-flight, energy, and angular resolution, and compare them to simulation results using a detailed Monte Carlo model. We also describe the balloon payload we have built for a test flight of the instrument in the fall of 2010.

Published

2010

17. GRAPE: a balloon-borne gamma-ray polarimeter

Author

Mark L. McConnell, James M. Ryan, Christopher M. Bancroft, Jason S. Legere, Taylor Connor, and Peter F. Bloser

Subjects

Physics, Photomultiplier, Photon, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, Polarimetry, Gamma ray, Compton scattering, Polarimeter, Astrophysics, Scintillator, Crab Nebula, Optics, business

Abstract

The Gamma-RAy Polarimeter Experiment (GRAPE) is a concept for an astronomical hard X-ray Compton polarimeter operating in the 50 - 500 keV energy band. The instrument has been optimized for wide-field polarization measurements of transient outbursts from energetic astrophysical objects such as gamma-ray bursts and solar flares. The GRAPE instrument is composed of identical modules, each of which consists of an array of scintillator elements read out by a multi-anode photomultiplier tube (MAPMT). Incident photons Compton scatter in plastic scintillator elements and are subsequently absorbed in inorganic scintillator elements; a net polarization signal is revealed by a characteristic asymmetry in the azimuthal scattering angles. We have constructed a prototype GRAPE module that has been calibrated at a polarized hard X-ray beam and flown on an engineering balloon test flight. A full-scale scientific balloon payload, consisting of up to 36 modules, is currently under development. The first flight, a one-day flight scheduled for 2011, will verify the expected scientific performance with a pointed observation of the Crab Nebula. We will then propose long-duration balloon flights to observe gamma-ray bursts and solar flares.

Published

2009

18. A new low-background Compton telescope using LaBr 3 scintillator

Author

Shawn Tornga, Manuel Julien, Peter F. Bloser, James M. Ryan, Mark S. Wallace, Jason S. Legere, Mark L. McConnell, R. Marc Kippen, and Christopher M. Bancroft

Subjects

Physics, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Compton telescope, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Gamma ray, Gamma-ray astronomy, Scintillator, law.invention, Telescope, Optics, Observatory, law, Neutron, business

Abstract

Gamma-ray astronomy in the MeV range suffers from weak fluxes from sources and high background in the nuclear energy range. The background comes primarily from neutron-induced gamma rays, with the neutrons being produced by cosmic-ray interactions in the Earth's atmosphere, the spacecraft, and the instrument. Compton telescope designs often suppress this background by requiring coincidences in multiple detectors and a narrow time-of-flight (ToF) acceptance window. The COMPTEL experience on the Compton Gamma Ray Observatory shows that a 1.9-ns ToF resolution is insufficiently narrow to achieve the required low background count rate. Furthermore, neutron interactions in the detectors themselves generate an irreducible background. By employing LaBr3 scintillators for the calorimeter, one can take advantage of the unique speed and resolving power of the material to improve the instrument sensitivity and simultaneously enhance its spectroscopic performance and thus its imaging performance. We present a concept for a balloon- or space-borne Compton telescope that employs deuterated liquid in the scattering detector and LaBr3 as a calorimeter and estimate the improvement in sensitivity over past realizations of Compton telescopes. We show initial laboratory test results from a small prototype, including energy and timing resolution. Finally, we describe our plan to fly this prototype on a test balloon flight to directly validate our background predictions and guide the development of a full-scale instrument.

Published

2009

19. Silicon photo-multiplier readouts for scintillators in high-energy astronomy

Author

Jason S. Legere, Mark L. McConnell, Christopher M. Bancroft, Peter F. Bloser, and James M. Ryan

Subjects

Physics, Scintillation, Optics, Silicon photomultiplier, Physics::Instrumentation and Detectors, High-energy astronomy, business.industry, Detector, Scintillation counter, Scintillator, Photonics, business, Low voltage

Abstract

New scintillator materials have recently been shown to hold great potential for low-cost, reliable gamma-ray detectors in high-energy astronomy. New devices for the detection of scintillation light promise to make scintillator-based instruments even more attractive by reducing mass and power requirements. In particular, silicon photo-multipliers (SiPMs) are starting to become commercially available that offer gains and quantum efficiencies similar to those of photo-multiplier tubes (PMTs), but with greatly reduced mass, high ruggedness, low voltage requirements, and no sensitivity to magnetic fields. We have conducted laboratory tests of a sample of commercially available SiPMs coupled to LaBr 3 :Ce, a scintillator of relevance to future high-energy astrophysics missions. We present results for gamma-ray spectroscopy, compare the SiPM performance to that of a PMT, and discuss the extent to which SiPMs offer significant advantages for scintillator-based space missions.

Published

2008