Your search keyword '"Kiss M."' showing total 7 results

1. Systematic effects on a Compton polarimeter at the focus of an X-ray mirror.

Author

Aoyagi, M., Bose, R.G., Chun, S., Gau, E., Hu, K., Ishiwata, K., Iyer, N.K., Kislat, F., Kiss, M., Klepper, K., Krawczynski, H., Lisalda, L., Maeda, Y., Malmborg, F. af, Matsumoto, H., Miyamoto, A., Miyazawa, T., Pearce, M., Rauch, B.F., and Rodriguez Cavero, N.

Subjects

*COMPTON imaging, *COMPTON effect, *FOCAL length, *X-ray optics

Abstract

XL-Calibur is a balloon-borne Compton polarimeter for X-rays in the ∼ 15–80 keV range. Using an X-ray mirror with a 12 m focal length for collecting photons onto a beryllium scattering rod surrounded by CZT detectors, a minimum-detectable polarization as low as ∼ 3% is expected during a 24-hour on-target observation of a 1 Crab source at 45° elevation. Systematic effects alter the reconstructed polarization as the mirror focal spot moves across the beryllium scatterer, due to pointing offsets, mechanical misalignment or deformation of the carbon-fiber truss supporting the mirror and the polarimeter. Unaddressed, this can give rise to a spurious polarization signal for an unpolarized flux, or a change in reconstructed polarization fraction and angle for a polarized flux. Using bench-marked Monte-Carlo simulations and an accurate mirror point-spread function characterized at synchrotron beam-lines, systematic effects are quantified, and mitigation strategies discussed. By recalculating the scattering site for a shifted beam, systematic errors can be reduced from several tens of percent to the few-percent level for any shift within the scattering element. The treatment of these systematic effects will be important for any polarimetric instrument where a focused X-ray beam is impinging on a scattering element surrounded by counting detectors. [ABSTRACT FROM AUTHOR]

Published

2024

2. Science prospects for SPHiNX – A small satellite GRB polarimetry mission.

Author

Pearce, M., Eliasson, L., Kumar Iyer, N., Kiss, M., Kushwah, R., Larsson, J., Lundman, C., Mikhalev, V., Ryde, F., Stana, T.-A., Takahashi, H., and Xie, F.

Subjects

*MICROSPACECRAFT, *GAMMA ray bursts, *ELECTROMAGNETIC fields, *CLASSIFICATION algorithms, *IMAGE quality analysis

Abstract

Abstract Gamma-ray bursts (GRBs) are exceptionally bright electromagnetic events occurring daily on the sky. The prompt emission is dominated by X-/ γ -rays. Since their discovery over 50 years ago, GRBs are primarily studied through spectral and temporal measurements. The properties of the emission jets and underlying processes are not well understood. A promising way forward is the development of missions capable of characterising the linear polarisation of the high-energy emission. For this reason, the SPHiNX mission has been developed for a small-satellite platform. The polarisation properties of incident high-energy radiation (50–600 keV) are determined by reconstructing Compton scattering interactions in a segmented array of plastic and Gd 3 Al 2 Ga 3 O 12 (Ce) (GAGG(Ce)) scintillators. During a two-year mission, ∼ 200 GRBs will be observed, with ∼ 50 yielding measurements where the polarisation fraction is determined with a relative error ≤ 10%. This is a significant improvement compared to contemporary missions. This performance, combined with the ability to reconstruct GRB localisation and spectral properties, will allow discrimination between leading classes of emission models. [ABSTRACT FROM AUTHOR]

Published

2019

3. Optimising a balloon-borne polarimeter in the hard X-ray domain: From the PoGOLite Pathfinder to PoGO+.

Author

Chauvin, M., Jackson, M., Kawano, T., Kiss, M., Kole, M., Mikhalev, V., Moretti, E., Takahashi, H., and Pearce, M.

Subjects

*POLARISCOPE, *COMPTON scattering, *SCINTILLATORS, *OPTICAL polarization, *NEUTRONS

Abstract

PoGOLite is a balloon-borne hard X-ray polarimeter dedicated to the study of point sources. Compton scattered events are registered using an array of plastic scintillator units to determine the polarisation of incident X-rays in the energy range 20–240 keV. In 2013, a near circumpolar balloon flight of 14 days duration was completed after launch from Esrange, Sweden, resulting in a measurement of the linear polarisation of the Crab emission. Building on the experience gained from this Pathfinder flight, the polarimeter is being modified to improve performance for a second flight in 2016. Such optimisations, based on Geant4 Monte Carlo simulations, take into account the source characteristics, the instrument response and the background environment which is dominated by atmospheric neutrons. This paper describes the optimisation of the polarimeter and details the associated increase in performance. The resulting design, PoGO+, is expected to improve the Minimum Detectable Polarisation (MDP) for the Crab from 19.8% to 11.1% for a 5 day flight. Assuming the same Crab polarisation fraction as measured during the 2013 flight, this improvement in MDP will allow a 5 σ constrained result. It will also allow the study of the nebula emission only (Crab off-pulse) and Cygnus X-1 if in the hard state. [ABSTRACT FROM AUTHOR]

Published

2016

4. Preflight performance studies of the PoGOLite hard X-ray polarimeter.

Author

Chauvin, M., Jackson, M., Kawano, T., Kiss, M., Kole, M., Mikhalev, V., Moretti, E., Takahashi, H., and Pearce, M.

Subjects

*PERFORMANCE theory, *POLARISCOPE, *HARD X-rays, *GEOMETRY, *PHOTON emission, *CRAB Nebula, *COMPTON scattering

Abstract

Polarimetric studies of astrophysical sources can make important contributions to resolve the geometry of the emitting region and determine the photon emission mechanism. PoGOLite is a balloon-borne polarimeter operating in the hard X-ray band (25–240 keV), with a Pathfinder mission focussing on Crab observations. Within the polarimeter, the distribution of Compton scattering angles is used to determine the polarisation fraction and angle of incident photons. To assure an unbiased measurement of the polarisation during a balloon flight it is crucial to characterise the performance of the instrument before the launch. This paper presents the results of the PoGOLite calibration tests and simulations performed before the 2013 balloon flight. The tests performed confirm that the polarimeter does not have any intrinsic asymmetries and therefore does not induce bias into the measurements. Generally, good agreement is found between results from test data and simulations which allows the polarimeter performance to be estimated for Crab observations. [ABSTRACT FROM AUTHOR]

Published

2016

5. Performance of the X-Calibur hard X-ray polarimetry mission during its 2018/19 long-duration balloon flight.

Author

Abarr, Q., Beheshtipour, B., Beilicke, M., Bose, R., Braun, D., de Geronimo, G., Dowkontt, P., Errando, M., Gadson, T., Guarino, V., Heatwole, S., Hossen, M., Iyer, N., Kislat, F., Kiss, M., Kitaguchi, T., Krawczynski, H., Lanzi, J., Li, S., and Lisalda, L.

Subjects

*HARD X-rays, *POLARIMETRY, *THRESHOLD energy, *POLARISCOPE, *X-rays, *BERYLLIUM, *X-ray scattering

Abstract

X-Calibur is a balloon-borne telescope that measures the polarization of high-energy X-rays in the 15–50 keV energy range. The instrument makes use of the fact that X-rays scatter preferentially perpendicular to the polarization direction. A beryllium scattering element surrounded by pixellated CZT detectors is located at the focal point of the InFOCµS hard X-ray mirror. The instrument was launched for a long-duration balloon (LDB) flight from McMurdo (Antarctica) on December 29, 2018, and obtained the first constraints of the hard X-ray polarization of an accretion-powered pulsar. Here, we describe the characterization and calibration of the instrument on the ground and its performance during the flight, as well as simulations of particle backgrounds and a comparison to measured rates. The pointing system and polarimeter achieved the excellent projected performance. The energy detection threshold for the anticoincidence system was found to be higher than expected and it exhibited unanticipated dead time. Both issues will be remedied for future flights. Overall, the mission performance was nominal, and results will inform the design of the follow-up mission XL-Calibur , which is scheduled to be launched in summer 2022. [ABSTRACT FROM AUTHOR]

Published

2022

6. Measuring energy dependent polarization in soft γ-rays using Compton scattering in PoGOLite

Author

Axelsson, M., Engdegård, O., Ryde, F., Larsson, S., Pearce, M., Hjalmarsdotter, L., Kiss, M., Bettolo, C. Marini, Arimoto, M., Björnsson, C.-I., Carlson, P., Fukazawa, Y., Kamae, T., Kanai, Y., Kataoka, J., Kawai, N., Klamra, W., Madejski, G., Mizuno, T., and Ng, J.

Subjects

*X-rays, *MAGNETIC fields, *GEOMETRY, *OPTICS

Abstract

Abstract: Linear polarization in X- and γ-rays is an important diagnostic of many astrophysical sources, foremost giving information about their geometry, magnetic fields, and radiation mechanisms. However, very few X-ray polarization measurements have been made, and then only mono-energetic detections, whilst several objects are assumed to have energy dependent polarization signatures. In this paper, we investigate whether detection of energy dependent polarization from cosmic sources is possible using the Compton technique, in particular with the proposed PoGOLite balloon-experiment, in the 25–100keV range. We use Geant4 simulations of a PoGOLite model and input photon spectra based on Cygnus X-1 and accreting magnetic pulsars (100mCrab). Effective observing times of 6 and 35h were simulated, corresponding to a standard and a long duration flight, respectively. Both smooth and sharp energy variations of the polarization are investigated and compared to constant polarization signals using chi-square statistics. We can reject constant polarization, with energy, for the Cygnus X-1 spectrum (in the hard state), if the reflected component is assumed to be completely polarized, whereas the distinction cannot be made for weaker polarization. For the accreting pulsar, constant polarization can be rejected in the case of polarization in a narrow energy band with at least 50% polarization, and similarly for a negative step distribution from 30% to 0% polarization. [Copyright &y& Elsevier]

Published

2007

7. XL-Calibur – a second-generation balloon-borne hard X-ray polarimetry mission.

Author

Abarr, Q., Awaki, H., Baring, M.G., Bose, R., De Geronimo, G., Dowkontt, P., Errando, M., Guarino, V., Hattori, K., Hayashida, K., Imazato, F., Ishida, M., Iyer, N.K., Kislat, F., Kiss, M., Kitaguchi, T., Krawczynski, H., Lisalda, L., Matake, H., and Maeda, Y.

Subjects

*HARD X-rays, *X-rays, *CADMIUM zinc telluride, *POLARIMETRY, *POLARISCOPE, *BALLOONING

Abstract

XL-Calibur is a hard X-ray (15-80 keV) polarimetry mission operating from a stabilised balloon-borne platform in the stratosphere. It builds on heritage from the X-Calibur mission, which observed the accreting neutron star GX 301 - 2 from Antarctica, between December 29th 2018 and January 1st 2019. The XL-Calibur design incorporates an X-ray mirror, which focusses X-rays onto a polarimeter comprising a beryllium rod surrounded by Cadmium Zinc Telluride (CZT) detectors. The polarimeter is housed in an anticoincidence shield to mitigate background from particles present in the stratosphere. The mirror and polarimeter-shield assembly are mounted at opposite ends of a 12 m long lightweight truss, which is pointed with arcsecond precision by WASP – the Wallops Arc Second Pointer. The XL-Calibur mission will achieve a substantially improved sensitivity over X-Calibur by using a larger effective area X-ray mirror, reducing background through thinner CZT detectors, and improved anticoincidence shielding. When observing a 1 Crab source for t day days, the Minimum Detectable Polarisation (at 99% confidence level) is ∼ 2 % · t day − 1 / 2 . The energy resolution at 40 keV is ∼ 5.9 keV. The aim of this paper is to describe the design and performance of the XL-Calibur mission, as well as the foreseen science programme. [ABSTRACT FROM AUTHOR]

Published

2021