Journal of Physical Studies 21(4), Article 4201 [5 pages] (2017)
DOI: https://doi.org/10.30970/jps.21.4201

SCINTILLATION PROPERTIES AND X-RAY LUMINESCENCE SPECTRA OF ZINC TELLURIDE AT CRYOGENIC TEMPERATURES

V. Mikhailik^{1}, S. Galkin², M. Rudko³, R. Gamernyk⁴, A. Hrytsak⁴, V. Kapustianyk^{3{,}4}, H. Kraus⁵, M. Panasiuk³, V. Rudyk³
¹Diamond Light Source, Harwell Science Campus, Didcot, OX11 0DE, UK
²Institute for Scintillation Materials, 60, Nauky Av., Kharkiv, UA-61072, Ukraine
³Scientific-technical and Educational Centre of Low Temperature Studies,
Ivan Franko National University of Lviv, 50, Drahomanov St., Lviv, UA-79005, Ukraine
⁴ Department of Physics, Ivan Franko National University of Lviv,
50, Drahomanov St., Lviv, UA-79005, Ukraine
⁵ Department of Physics, University of Oxford, Keble Rd., Oxford, OX1 3RH, UK

The paper is devoted to the study of X-ray luminescence spectra, the scintillation light output and the decay time characterisation of undoped ZnTe at low temperatures down to 6\,K. Also, the photoconductivity spectrum in a visible region has been investigated. Due to significant thermal quenching, the scintillations at $\alpha$-particle excitation were detected in the sample only below $T=150$ K. The emission of the crystal is attributed to the radioactive recombination of the holes trapped by Zn vacancies and electrons captured at the shallow levels of impurities or defects. The scintillation efficiency increased with further cooling. It has been found that at $\alpha$-particle excitation undoped ZnTe exhibits a fairly competitive light output equal to $117\pm20\%$ of CaWO$_4$ reference scintillator. This finding underpins potential applications of ZnTe as a scintillation detector in the cryogenic experiments, particularly for the cryogenic search for neutrinoless double beta decay of $^{130}$Te. It has been also found that ZnTe will be attractive as a conventional scintillation detector at the temperature of liquid nitrogen ($T=77$ K). At this temperature, the scintillator exhibits a reasonably short decay time and a sufficient scintillation response to particle excitation. A practical implementation of this idea poses no real technical challenge since photomultipliers and Si-based photodetectors are proven to operate reliably and efficiently at this temperature.

PACS number(s): 29.40.Mc, 32.30.Rj, 78.90.+t