A comparative study on the performance of radiation detectors from the HgI2 crystals grown by different techniques

Martins, J. F. T.; Costa, F. E.; dos Santos, R. A.; de Mesquita, C. H.; Hamada, M. M.

Artykuł - szczegóły

Tytuł artykułu

A comparative study on the performance of radiation detectors from the HgI2 crystals grown by different techniques

Autorzy

Martins J. F. T. , Costa F. E. , dos Santos R. A. , de Mesquita C. H. , Hamada M. M.

Treść / Zawartość

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martins_A comparative study on the performance of radiation detectors.pdf

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Warianty tytułu

Konferencja

Proceedings of the International Conference on Development and Applications of Nuclear Technologies NUTECH-2011, 11-14 September 2011, Kraków, Poland

Języki publikacji

Abstrakty

In this work, the establishment of a technology for HgI2 purification and crystal growth is described, aiming at a future application of this crystal as a room temperature radiation semiconductor detector. Two methods of crystal growth were studied in the development of this work: (1) physical vapor transport (PVT) and (2) saturated solution from dimethylsulphoxide (DMSO) complexes. In order to evaluate the crystals obtained using each of these methods, systematic measurements were carried out for determining the stoichiometry, structure, orientation, surface morphology and impurity of the crystal. The influence of these physicochemical properties of the crystals developed was evaluated in terms of their performance as a radiation detector. The best response to radiation was found for the crystals grown by the PVT technique. Significant improvement in the performance of HgI2 radiation detector was found, purifying the crystal by means of two successive growths by the PVT technique.

Słowa kluczowe

crystal growth iodide mercury crystal physical vapor transport (PVT) radiation detector semiconductor crystal

Wydawca

Institute of Nuclear Chemistry and Technology

Czasopismo

Nukleonika

Rocznik

2012

Tom

Vol. 57, No. 4

Strony

555--562

Opis fizyczny

Bibliogr. 26 poz., rys.

Twórcy

autor

Martins J. F. T.

autor

Costa F. E.

autor

dos Santos R. A.

autor

de Mesquita C. H.

autor

Hamada M. M.

Institute for Nuclear and Energy Research (IPEN-CNEN/SP), 2242 Prof. Lineu Prestes Ave., Cidade Universitária, 05508-000, Săo Paulo – SP, Brazil, Tel.: +55 11 3133 9779, Fax: +55 11 3133 9765

Bibliografia

1. Ariesanti E, Kargar A, McGregor DS (2010) Fabrication and spectroscopy results of mercuric iodide Frisch collar detectors. Nucl Instrum Methods Phys Res A 624;3:656–661
2. Ariesanti E, Kargar A, McGregor DS (2010) Vapor growth of tetragonal prismatic mercuric iodide crystals. In: Nuclear Science Symposium Conference Record (NSS/MIC), 2010 IEEE, Knoxville, USA, 1:3739–3745
3. Ayres F, Machado WVM, Justo JF, Assali LVC (2003) Defects in mercuric iodide: an APW investigation. Physica B 340:918–922
4. Coleman CC (1970) Growth of large HgI2 single crystals. J Cryst Growth 6;2:203–204
5. Cummings T, Marin C, Ostrogorskya AG, Burgerc A, Blissd M (2006) Tetragonal red and yellow HgI2-CdI2 crystals for X- and γ-ray solid-state detectors directionally solidified under argon pressure of 20 atm. J Cryst Growth 297:334–338
6. Gang X, Wanqi J, Gaohong L, Xiaoyan S (2010) Heat treating and detectors characterization of α-HgI2. Rare Met Mater Eng 39;12:2088–2090
7. Heller S, Zanzonic P (2011) Nuclear probes and intraoperative gamma cameras review article. Semin Nucl Med 41;3:166–181
8. Hitomi K, Muroi O, Shoji T, Suehiro T, Hiratate Y (1999) Room-temperature X- and gamma-ray detectors using thalium bromide crystals. Nucl Instrum Methods Phys Res A 436:160–164
9. Hitomi K, Shoji T, Suehiro T, Hiratate Y (1999) Radiation damage effects by 25 MeV protons and thermal annealing effects on thalium bromide nuclear radiation detectors. IEEE Trans Nucl Sci 46:213–217
10. James JE, Baciak E, He Z (2003) Comparison of 5 and 10 mm thick HgI2 pixelated γ-ray spectrometers. Nucl Instrum Methods Phys Res A 505;1:191–194
11. Kaldis E (2001) Growth of mercuric iodide bulk crystals. In: Buschow KHJ (ed.) Encyclopedia of materials: Science and technology, Elsevier, Amsterdam, pp 5333–5337
12. Knoll GF (1989) Radiation detection and measurement, 2nd ed. Wiley, New York
13. Lund JC, Olschner F, Burger A (1995) Lead iodide crystals and detectors. In: Schlesinger TE, James RB (eds) Semiconductors for room temperature nuclear detector applications, semiconductors and semimetals. Vol. 43. Academic Press, San Diego, pp 443–464
14. Marcondes RM, Martins JFT, Santos RA, Costa FE, Gennari RF, Hamada MM (2011) The physical vapor transport as a technique for purification and growth of the HgI2 crystal. In: 2011 Int Nuclear Atlantic Conf (INAC/ENAN), INAC2011, Belo Horizonte, Brazil
15. Martín-Gil J, Martín-Gil FJ, De Andrés Santos AI, Ramos-Sánchez MC, Barrio-Arredondo MT, Chebib-Abuchala N (1997) Thermal behaviour of medical grade silicone oils. J Anal Appl Pyrolysis 42;2:151–158
16. McGregor DS, Hermon H (1997) Room-temperature compound semiconductor radiation detectors. Nucl Instrum Methods Phys Res A 395;1:101–124
17. McLaughlin JP (eds) (2005) The natural radiation environment. Vol. 7. Elsevier, London
18. Oliveira IB, Costa FE, Chubaci JFD, Hamada MM (2004) Purification and preparation of TlBr crystals for room temperature radiation detector applications. IEEE Trans Nucl Sci 51:1224–1228
19. Owensa A, Bavdaz M, Brammertz G et al. (2003) The X-ray response of TlBr. Nucl Instrum Methods Phys Res A 497:370–380
20. Ponpon JP, Amann M (2006) Etching of mercuric iodide in cation iodide solutions. Appl Surf Sci 252;18:6313–6322
21. Rao MR, Verma JKD (1980) Solution grown mercuric iodide crystals as low-energy gamma-ray conduction type detectors. Appl Phys 13;8:1545–1550
22. Ricker GR, Vallerga JV, Wood DR (1983) A mercuric iodide detector system for X-ray astronomy: I. Design considerations and predictions of background and sensitivity. Nucl Instrum Methods Phys Res A 213:133–144
23. Ugucioni JC, Neto Ghilardi T, Mulato M (2010) Mercuric iodide crystals obtained by solvent evaporation using ethanol. Nucl Instrum Methods Phys Res A 615:259–266
24. Weiguang Y, Lei N, Dongmei L et al. (2011) Growth of oriented polycrystalline α-HgI2 films by ultrasonic-wave-assisted physical vapor deposition. J Cryst Growth 324;1:149–153
25. Wilson MD, Cernik C, Chen H et al. (2011) Small pixel CZT detector for hard X-ray spectroscopy. Nucl Instrum Methods Phys Res A 652:158–161
26.Zhou HT, Lee CH, Chung JM, Shin CT, Chiu KC, Lan SM (2003) Growth of α-HgI2 single crystals from physical vapor transport in an oil-bath furnace. Mater Res Bull 38;15:1987–1992

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