Abstract
The polarisation of astrophysical source emission in the energy range from a few tens of keV up to the MeV region is an almost unexplored field of high-energy astrophysics. Till date, polarimetry in astrophysics–in the energy domain from hard X-rays up to soft γ-rays–has not been pursued due to the difficulties involved in obtaining sufficient sensitivity. Indeed for those few instruments that are capable of performing this type of measurement (e.g. the COMPTEL instrument on the Compton Gamma-ray Observatory and the IBIS instrument on INTEGRAL), polarimetry itself plays a secondary role in the mission objectives, as the efficiencies (0.5% and 10% maximum, respectively) and polarimetric Q factors (0.1 and 0.3, respectively) are relatively limited. In order to perform efficient polarimetric measurements for hard X-ray and soft gamma-ray sources, with an instrument of relatively robust and simple design, a CdTe based telescope (CIPHER: Coded Imager and Polarimeter for High Energy Radiation) is under study. This instrument is based on a thick (10 mm) CdTe position-sensitive spectrometer comprising four modules of 32 × 32 individual pixels, each with a surface area of 2 × 2 mm2 (about 160 cm2 total detection area). The polarimetric performance and design optimisation of the CIPHER detection surface have been studied by use of a Monte Carlo code. This detector, due to its intrinsic geometry, can allow efficient polarimetric measurements to be made between 100 keV and 1 MeV. In order to predict the polarimetric performance and to optimise the design and concept of the CIPHER detection plane, a Monte Carlo code based on GEANT4 library modules was developed to simulate the detector behaviour under a polarised photon flux. The Compton double event efficiency, as well bi-dimensional double event distribution maps and the corresponding polarimetric modulation factor will be presented and discussed. Modulation Q factors better than 0.50 and double event total efficiencies greater than 10% were calculated in the energy range between 100 keV and 1 MeV. Herein we will present and discuss the general problems that affect polarimetric measurements in space, such as the inclination of the source with respect to the telescope optical axis and background radiation. Q factor calculations for several beam inclinations as well as for background together with simulated astronomical sources will be presented and discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aprile, E., Bolotnikv, A., Chen, D., Mukherjee, R. and Xu, F.: 1994, Astrophys. J. Suppl. 92, 689.
Caroli, E., Bertuccio, G., Cola, A., Curado da Silva, R. M., Donati, A., Dusi, W., Landini, G., Siffert, P., Sampietro, M. and Stephen, J. B.: 2000, 'Hard X-ray polarimetry with a thick CdTe position sensitive spectrometer', SPIE Proceedings on X-ray and Gamma-ray instrumentation for Astronomy XI, Vol. 4140, pp. 573–583.
Caroli, E., Stephen, J. B., Dusi, W., Bird, A. J., Dean, A. J., Bertuccio, G., Sampietro, M., Yu, W., Zhang, C., Curado da Silva, R. M., Siffert, P. and Reglero, V.: 2000, 'The CIPHER telescope for hard X and soft gamma-ray polarimetry', in M. L. McConnell and J. M. Ryan (eds), Proceed-ing Series of American Institute of Physics on The Fift Compton Symposium, AIP Conference Proceeding, Vol. 510, pp. 809–813.
Curado da Silva, R. M., Caroli, E., Stephen, J. B. and Siffert, P.: 2002, Proc. SPIE 4497 70–78.
Gehrels, N. and Winkler, C.: 1996, SPIE Proc. 2806, 210–216.
Kroeger, R. A., Johnson, W. N., Kinzer, R. L., Kurfess, J. D., Inderhees, S. E., Philips, B. F. and Graham, B.: 1996, 'Gamma ray instrument for polarimetry, spectroscopy, and imaging (GIPSI), SPIE Proceedings on Gamma-Ray and Cosmic-Ray Detectors, Techniques, and Missions, Vol. 2806, pp. 52–63.
Lei, F., Dean, A. J. and Hills, G. L.: 1997, Space Sci. Rev. 82, 309–388.
Matt, G., Feroci, M., Rapisarda, M. and Costa E.: 1996, Radiat. Phys. Chem. 48, pp. 403–411.
Namito, Y., Ban, S. and Hirayama: 1993, Nucl. Inst. Meth., A 332, 277–283.
Parsons, A. M., Stahle, C. M., Lisse, C. M., Babu, S., Gehrels, N. A., Teegarden, B. J. and Shu, P. K.: 1994, 'Room temperature semiconductor detectors for hard X-ray astrophysics', SPIE Proceedings on Gamma-ray Detector Physics and Application, Vol. 2305, pp. 121–132.
Schönfelder, V. et al.: 1993, Astrophys. J. Suppl. 86, 657.
Slavis, K. R., Dowkontt, P., Duttweiler, F., Epstein, J., Hink, P., Huszar, G., Kalemci, E., Leblanc, P., Matteson, J., Pelling, M. R., Rothschild, R. E., Stephan, E., Tumer, T. and Visser, G.: 2000, 'Performance of a prototype CdZnTe detector module for hard X-ray astrophysics', SPIE Pro-ceedings on X-Ray and Gamma-Ray Instrumentation for Astronomy XI, Vol. 4140, pp. 249–256.
Stephen, J. B., Caroli, E., Curado da Silva, R. M. and Foschini, L.: 2001, 'Gamma-ray polarisation measurements with INTEGRAL/IBIS', AIP Conference Proceedings series, presented in Gamma-Ray Astrophysics 2001, Baltimore, Maryland, U.S.A.
Swinyard, B. M., Didcot C., Malaguti, G., Caroli, E., Dean, A. J. and Di Coco, G.: 1991, Proc. SPIE 1548, 94–105.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Curado Da Silva, R.M., Caroli, E., Stephen, J. et al. Cipher, A Polarimeter Telescope Concept for Hard X-Ray Astronomy. Experimental Astronomy 15, 45–65 (2003). https://doi.org/10.1023/B:EXPA.0000028168.26442.30
Published:
Issue Date:
DOI: https://doi.org/10.1023/B:EXPA.0000028168.26442.30