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Название статьи THERMOLUMINESCENT DETECTORS FOR SURVEILLANCE STUDIES OF RADIATION EXPOSURE OF THE POPULATION
Авторы

Aluker N., Kemerovo State University, Krasnaya Str. 6, Kemerovo, 650043 Russian Federation, naluker@gmail.com

Suzdal’tseva Ya., Institute of Human Ecology of the Siberian Branch of the Russian Academy of Sciences, Leningradsky Ave. 10, Kemerovo, 650065 Russian Federation

Dulepova A., Kemerovo State University, Krasnaya Str. 6, Kemerovo, 650043 Russian Federation

Herrmann M., Pennsylvania State University, 405a Walker Building University Park, PA 16802 USA

Раздел: CHEMICAL SCIENCES
Год 2016 Номер журнала 2 DOI 10.21603/2500-1418-2016-1-2-3-10
Аннотация Luminescent glow occurring in a substance exposed to ionizing radiation (IR) in the process of heating, thermoluminescence (TL) is now an effective method of registration of radiation-absorbed doses. It is important to be aware that the correct absorbed dose when exposed to mixed radiation with unknown characteristics is determined in the material of detector as well as in materials similar in composition (Z eff) and density [1-3]. In this connection, it is expedient to use different types of detectors for solution of different dosimetric problems. This study gives a comparison of the performance characteristics of TLD-K thermoluminescent detectors [4, 5], made of sodium silicate glass ceramic with the characteristics of IR detectors made of luminophors based on lithium fluoride monocrystals containing impurities of titanium and magnesium (TLD -100) [6, 7] and an anion of defective aluminum oxide (TLD-500) [8-11] widely used in thermoluminescence dosimetry. Comparison of a number of parameters that are relevant to the use of detectors in dosimetric monitoring of environment favors TLD-K detectors. The studies were carried out on the territory of the Kemerovo region.
Ключевые слова Thermoluminescence, detectors, ionizing radiation, absorbed dose, environment
Информация о статье Дата поступления 5 апреля 2016 года
Дата принятия в печать 24 мая 2016 года
Дата онлайн-размещения 30 декабря 2016 года
Выходные данные статьи Aluker N., Suzdal’tseva Y., Dulepova A., Herrmann M. THERMOLUMINESCENT DETECTORS FOR SURVEILLANCE STUDIES OF RADIATION EXPOSURE OF THE POPULATION. Science Evolution, 2016, vol. 1, no. 2, pp. 3-10. doi:10.21603/2500–1418–2016–1–2–3–10.
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Список цитируемой литературы
  • Ivanov V.I. Kurs dozimetrii [Dosimetry Course], Moscow, 1998. 100 p.
  • Frank M., Stolz V. Tverdotel'naya dozimetriya ioniziruyushchego izlucheniya [Solid State Dosimetry of Ionizing Radiation]. Moscow: Atomizdat, 1973. 248 p.
  • Jaeger R. Dosimetry and radiation protection (physical and technical constants) (Russ. ed.: Jaeger R. Dozimetriya i zashchita ot izlucheniy (fizicheskie i tekhnicheskie konstanty)). Translated from German. Moscow: Atomizdat, 1961. 212 p.
  • Aluker N., Aluker V. Proc. 10–th International Conference on Solid State Dosimetry. Ashford, Kent: Nuklear Technology Publishing PO, 1992, no. 7, p. 39.
  • Aluker N.L., Aluker E. D. Rabochee veshchestvo dlya termolyuminestsentnogo dozimetra ioniziruyushchikh izlucheniy [Working substance for thermoluminescent dosimeter of ionizing radiations]. Patent RF, no. 2108598, 1998.
  • Fominykh V.I., Oborin F.V. Issledovanie kharakteristik termolyuminestsentnykh detektorov na osnove LiF [Study of characteristics of LiF– based thermoluminescent detectors]. Izotopy v SSSR [Isotopes in the USSR], 1982, vol. 63, pp. 12–19.
  • Shvarts K.K., Grant Z.A., Mezhs T.K., Grube M.M. Termolyuminestsentnaya dozimetriya [Thermoluminescent dosimetry]. Riga: Zinatne Publ., 1967, p. 180.
  • Aksel'rod, M.S. Kortov V.S., Mil'man I.I., Gorelova E.A., Borisov A.A., Zatulovskiy L.M., Kraevetskiy D.Ya., Berezina I.E., Lebedev N.K. Izv. AN SSSR [News of AS USSR]. Set. Fiz., 1988, vol. 52, no.10, pp. 1981–1984.
  • Kortov V.S., Mil'man I.I., Nikiforov S.V. Osobennosti kinetiki termostimulirovannoy lyuminestsentsii kristallov α–Al2O3 s defektami [Specific features in the kinetics of thermally stimulated luminescence of α–Al2O3 crystals containing defects]. Fizika tverdogo tela [Solid state physics], 1997, vol. 39, no. 9, pp. 1538–1543.
  • Nikiforov S.V. Osobennosti termostimulirovannoy lyuminestsentsii aniondefektnogo α–Al2O3, Avtoref. diss. kand. fiz.–mat. nauk [Features of thermally stimulated luminescence of anion–defective α–Al2O3. Cand. phys–math. sci.]. Ekaterinburg, 1998. 18 p.
  • Mil'man I.I. Termostimulirovannye protsessy v obluchennykh shirokozonnykh oksidakh s narushennoy stekhiometriey, Avtoref. diss. kand. fiz.–mat. nauk [Thermally stimulated processes in irradiated wide–band oxides with impaired stoichiometry. Cand. phys–math. sci.]. Ekaterinburg, 1999. 48 p.
  • Antonov-Romanovskiy V.V. Kinetika fotolyuminestsentsii kristallofosforov [Kinetics of crystal phosphor photoluminescence]. Moscow: Nauka Publ., 1966. 324 p.
  • McKeever S.V.S. Thermoluminescence dosimetry materials: properties and uses. Ashford: Nuclear Technology Publishing, 1995. 214 p.
  • Bochvar I.A. Vasil'eva A.A., Keirim–Markus I.B., Prosina T.I., Syritskaya Z.M., Yakubik V.V. Dozimetry ioniziruyushchikh izlucheniy, osnovannye na izmerenii termolyuminestsentsii amorfnykh stekol (dozimetry IKS) [Radiation dosimeters based on thermoluminescence measurements in amorphous glass (iks dosimeters) (ICS dosimeters)]. Moscow: Atenergiya Publ., 1963, pp. 48–52.
  • Aluker N.L., Artamonov A.S., Bakulin Yu.P., Danilevich E.N., Krysanova O.L., Riskina R.V., Sogoyan A.V. Termolyuminestsentnyy detektor TLD–K na osnove SiO2 [Thermoluminescent TLD–K SiO2–based detector]. Voprosy atomnoy nauki i tekhniki. Seriya: Fizika radiatsionnogo vozdeystviya na radioelektronnuyu apparaturu [Problems of Atomic Science and Technology. Series: Physics of radiation effects on radioelectronic equipment], 2006, no. 3–4, pp. 86–88.
  • Aluker N.L., Suzdal'tseva Ya.M., Chernov A.N. Otsenka predel'nykh vremennykh vozmozhnostey datirovaniya chetvertichnykh otlozheniy termolyuminestsentnym metodom [Evaluation of quaternary deposits time limit potential dating using thermo– luminescent method]. Geologiya i mineral'no–syr'evye resursy Sibiri [Geology and Mineral Resources of Siberia], 2014, no.4, pp. 29–35.
  • Aluker N.L., Bobrov V.V., Suzdal’tseva Ya.M. Parameters of traps essential for thermoluminescent dating of archaeological ceramics. Inorganic Materials, 2015, vol. 51, no. 2, pp. 182–186.
  • Komarova Ya.M., Aluker N.L., Bobrov V.V., Sorokina N.V. Thermoluminescent dating of archaeological pottery. Inorganic Materials, 2011, vol. 47, no. 5, pp. 544–548.
  • Petukhov A.V, Kapina I.S., Postel'nikov S.A., Aluker E.D., Aluker N.L., Lur'e A.M., Mozhaev B.N., Farrakhov E.G., Katskov N.K. Sposob geohimicheskih poiskov zalezhej nefti i gaza [Geochemical Methods of Prospecting and Exploration for Petroleum and Natural Gas]. Patent RF no. 4605801/25, 1988.
  • Aluker E.D., Kucheruk E.V., Petukhov A.V. Geokhimicheskie metody poiskov nefti i gaza v SSSR i za rubezhom [Geochemical methods of prospecting oil and gas in the USSR and abroad ]. Itogi nauki i tekhniki: Seriya Geokhimiya. Mineralogiya. Petrografiya [Results of science and technology: Series: Geochemistry. Mineralogy. Petrography], 1989, vol. 16. 190 p.
  • Aluker N.L, Sorokina N.V. Territorial'nyy radioekologicheskiy monitoring na osnove termolyuminestsentnoy dozimetrii [Regional radioecological environmental monitoring on the basis of thermoluminescent dosimetry]. Zhurnal "Bezopasnost' zhiznedeyatel'nosti" ["Health and Safety" magazine], 2005, no. 12, pp. 38–43.
  • Aluker N.L., Aluker E.D., Eremenko A.N., Popov V.L., Malakhova N.G. Primenenie individual'nykh dozimetrov TLD–K dlya dozimetricheskogo monitoringa v Kuzbasse [Use of TLD–K personal dosimeters for the dosimetric monitoring in the Kuzbass]. Problemy obespecheniya ekologicheskoy bezopasnosti v Kuzbasskom regione KO REA [Problems of environmental security in the Kuzbass region KB REA], 1999, pp. 74–91.
  • Aluker N.L., Yagodina E.V. Effect of Radiation, Biological Dosimetry, and Protection Against Radiation. Novel materials and technologies for space rockets, 2011, pp. 341–347.

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Последний выпуск: Science Evolution, Vol. 2, no. 1, 2017