RU2149426C1 - Method of preparing lithium fluoride-based thermoluminescent detector of ionizing radiations - Google Patents

Abstract

FIELD: radiotechnology. SUBSTANCE: invention relates to measuring nuclear emission and is designed to measuring values of ionizing radiations in individual dosimetry. Lithium fluoride is mixed with cuprous fluoride, magnesium chloride, and ammonium phosphate to give mixture, which is dried for 4 h at 80 C and then heated at 1050-1200 C for 30 min under nitrogen atmosphere and cooled for 30 min to 400 C. Resulting thermoluminescent phosphor is broken down and fraction 80-150 mesh is isolated, cooled to ambient temperature, irradiated by gamma-emission from ⁶⁰Co source, annealed at 250 C for 10 min, recooled to ambient temperature, and reannealed for 0.5-3 h. EFFECT: increased intensity of thermoluminescent deexcitation in manufactured thermoluminescent detector.

Description

 The inventive method relates to the field of measurement of ionizing radiation. The most effectively claimed method can be used to obtain thermoluminescent detectors (TLDs) used in thermoluminescent dosimeters designed to determine the doses of ionizing radiation received by any objects.

The use of TLDs in thermoluminescent dosimeters is based on the fact that after its irradiation with any ionizing radiation, TLDs are heated in a linear mode with a constant heating rate in the range from 0.05 to 50 ^o / s, the intensity of thermoluminescent emission of the heated TLD is measured, and a dependence curve is built intensity of thermoluminescent emission from the heating temperature (KTV) and determine the radiation dose as proportional to the area bounded by the built-in curve [1], as well as the time between the moment of irradiation and the moment m readings with TLD [2]. The determination of the above time is especially important in cases of using TLDs based on lithium fluoride for individual dosimetric control (insofar as the effective atomic number of TLDs based on lithium fluoride, equal to 8.2, is closest to the effective atomic number of soft biological tissue, equal to 7.2, then lithium fluoride-based TLDs are best suited for individual dosimetric monitoring compared to alumina, calcium fluoride or calcium sulfate TLDs).

 The intensity of thermoluminescent luminescence of TLDs when it is heated is equal to the response of TLDs to the unit of dose received by it. A change (over time) in the intensity of thermoluminescent flashing of TLDs is characterized by fading (loss of stored dosimetric information after termination of TLD irradiation due to activation and / or tunnel delocalization of charge carriers) [3], and the speed of fading at different heating temperatures for the same TLD can be are different.

 Since the fading speed of lithium fluoride-based TLDs in regions of elevated temperatures is lower than the similar fading speed in low-temperature regions, high-temperature thermoluminescent luminescence of TLDs based on lithium fluoride is used to determine the received dose of ionizing radiation, and low-temperature to determine the time elapsed since the moment of exposure to the moment of taking readings from the irradiated TLD.

A known method of producing TLDs based on lithium fluoride [4], comprising mixing in water lithium fluoride with activators (copper fluoride and magnesium chloride) and a sensitizer (ammonium silicate), drying the resulting mixture at 80 ^o C for 4 hours, holding the dried mixture at 1050 ^o C for 30 minutes in a nitrogen atmosphere, its cooling for 30 minutes to 400 ^o C, grinding the obtained thermoluminescent phosphorus, isolating the fraction with a dispersion of 80-150 mesh, cooling to room temperature and irradiation with γ-radiation from a source of Co ⁶⁰ . After the above operations, the obtained TLD (LiF: Mg, Cu, Si) is ready for use in thermoluminescent dosimeters.

The disadvantage of this method is that the obtained TLD has a reduced sensitivity [5] to the measured ionizing radiation and a reduced intensity of thermoluminescent emission in the low-temperature region, characterized by a KTV peak with a maximum at 120 ^o C, which does not allow the use of the known TLD to determine the time elapsed since the moment of exposure to the moment of taking readings from the irradiated TLD.

A known method of producing TLDs based on lithium fluoride [4], comprising mixing in water lithium fluoride with activators (copper fluoride and magnesium chloride) and a sensitizer (boric acid), drying the mixture at 80 ^o C for 4 hours, holding the dried mixture at 1050 ^o C for 30 minutes in a nitrogen atmosphere, its cooling for 30 minutes to 400 ^o C, grinding the obtained thermoluminescent phosphorus, isolating the fraction with a dispersion of 80-150 mesh, cooling to room temperature and irradiation with γ-radiation from a source of Co ⁶⁰ . After the above operations, the obtained TLD (LiF: Mg, Cu, B) is ready for use in thermoluminescent dosimeters.

 The disadvantage of this method is that the obtained TLD has a reduced sensitivity [5] to the measured ionizing radiation and increased fading speed in all heating regions of the irradiated TLD.

The closest analogue to the claimed method is a method for producing TLDs based on lithium fluoride [4], comprising mixing in water lithium fluoride with activators (copper fluoride and magnesium chloride) and a sensitizer (ammonium phosphate), drying the resulting mixture at 80 ^o C for 4 hours, extract the dried mixture at 1050 ^o C for 30 minutes in a nitrogen atmosphere, cooling it for 30 minutes to 400 ^o C, grinding the obtained thermoluminescent phosphorus excretion fraction dispersity 80-150 mesh, its cooling to room temperature, bluchenie γ-radiation from Co ⁶⁰ source and annealing at 250 ^o C for 10 minutes.

The KTV for the above TLD irradiated with ionizing radiation is characterized by three peaks: a low-temperature peak with a maximum of 120 ^o C and two high-temperature peaks at 170 ^o C and 210 ^o C. Thermoluminescent emission, characterized by both high-temperature peaks of the KTV, has a higher intensity for a rather long time ( the fading rate is less than 1% per year) compared with the intensity of thermoluminescent flashing, characterized by the low-temperature peak of KTV, which is insignificant flax and degrades to the background value for a short time (in no more than 4 hours at a temperature of 16 -24 ^o C).

Obtained in a known manner TLD:
- it is not possible to accurately determine the time elapsed from the moment of irradiation to the moment of taking readings from the irradiated TLD, due to the rapid degradation of the intensity of thermoluminescent luminescence, characterized by the low-temperature peak of KTV, to its background value;
- it is not possible to measure small doses of ionizing radiation, due to the low intensity in this case of the thermoluminescent emission of TLDs, characterized by both high-temperature peaks of KTV, i.e. due to the reduced sensitivity of the known TLD to small doses of ionizing radiation.

The disadvantage of this method is the low quality obtained as a result of its implementation TLD, due to:
- reduced intensity of its thermoluminescent luminescence, characterized by a low-temperature peak of KTV;
- reduced intensity of its thermoluminescent emission, characterized by two high-temperature peaks of the CTB in the case of TLD irradiation with small doses of ionizing radiation.

The advantage of the proposed method is to improve the quality of the obtained TLD by increasing it in comparison with the TLD of the closest analogue:
- intensities of thermoluminescent flashing, characterized by a low-temperature peak of KTV;
- the intensities of thermoluminescent emission, characterized by both high-temperature peaks of KTV in the case of TLD irradiation with small doses of ionizing radiation.

These advantages are achieved due to the fact that the inventive method for producing TLDs based on lithium fluoride involves mixing lithium fluoride in water with activators (copper fluoride and magnesium chloride) and a sensitizer (ammonium phosphate), drying the resulting mixture at 80 ^o C for 4 hours, extract dried mixture at 1050 - 1200 ^o C for 30 minutes in a nitrogen atmosphere, cooling it for 30 minutes to 400 ^o C, grinding the obtained thermoluminescent phosphorus excretion fraction dispersity 80-150 mesh, its cooling to room tempera urs, irradiation of γ-radiation from Co ⁶⁰ source, annealing at 250 ^o C for 10 minutes, again cooled to room temperature and a second annealing at 150-300 ^o C for 0.5-3 hours.

Distinctive features of the proposed method are the holding temperature of the dried mixture, which is in the temperature range with a lower limit, a large 1050 ^o C and an upper limit of 1200 ^o C, as well as the operation of re-cooling to room temperature and re-annealing of crushed and annealed at 250 ^o C thermoluminescent phosphorus LiF : (Mg, Cu, P) at 150-300 ^o C for 0.5-3 hours.

As a result of the above operations, the KTV of the obtained TLD after its irradiation with ionizing radiation is also characterized by three peaks: a low temperature peak with a maximum at 120 ^o C and two high temperature peaks at 170 ^o C and 210 ^o C, and the intensity of thermoluminescent emission, characterized by two high temperature peaks of the KTV, also stable for a long time (fading rate is less than 1% per year). However, in contrast to the closest analogue for TLD obtained according to the claimed method, the intensity of thermoluminescent flashing, characterized by a low-temperature peak of KTV, is higher than that of TLD of the closest analogue, which is confirmed by the fact that the degradation time of the intensity of the indicated thermoluminescent flashing is on average 44 - 56 days at a temperature of 16 - 24 ^o C. In addition, the intensity of thermoluminescent flashing, characterized by high-temperature peaks KTV, obtained according to declare When the method of TLD is irradiated with small doses of ionizing radiation, it is on average 5-6 times higher than the similar intensity of thermoluminescent emission in TLDs of the closest analogue.

If the temperature of the exposure of the mixture is less than 1050 ^o C or more than 1200 ^o C, the temperature of the re-annealing of thermoluminescent phosphorus is less than 150 ^o C or more than 300 ^o C, and the time of re-annealing is less than 0.5 or more than 3 hours, then obtain TLD with the above properties will be impossible.

 The inventive method is implemented as follows.

Lithium fluoride is mixed in water with 0.01-0.1 mol% of copper fluoride, 0.05-0.40 mol. % magnesium chloride and 0.005-10.01 mol.% ammonium phosphate. The resulting mixture was dehydrated at 80 ^o C for 4 hours, after which it was kept in a platinum crucible at 1100 ^o C for 30 minutes in a nitrogen atmosphere. The melt is cooled for 30 minutes to 400 ^o C. The synthesized thermoluminescent phosphorus LiF: (Mg, Cu, P) is crushed in a ball mill, a fraction with a dispersion degree of 115 mesh is isolated on a sieve, cooled to room temperature and irradiated with γ-radiation from the source Co ⁶⁰ with a dose of 165 rad. After irradiation, thermoluminescent phosphorus with a thickness of 2-4 mm is placed on a molybdenum substrate and annealed at 250 ^° C for 10 minutes, then cooled to room temperature and then annealed at 225 ^° C for 1.5 hours under similar conditions.

 As a result of the tests, it was found that the TLD obtained in this way has all the above advantages compared to the TLD obtained by the closest analogue method.

LITERATURE
1. T. Nakajima, Y. Murayama, T. Matsuzawa, "Preparation and Dosimetris Propertis of a Highly Sensitive LiF Thermoluminescent Dosimeter", Health Physics. Vol. 36 (January), p. 80, Pergamon Press Ltd., 1979. Printed in Great Britain.

 2. Z. Spurny, "Simultaneous estimation of exposure and time elapsed since exposure using multipeaked thermoluminescent phosphors", Health Physics Pergamon Press, Vol. 21, hh. 755-761, 1971.

 3. V.K. Vlasov, N.A. Karpov, V.V. Karezin, O.V. Kiryukhin, A.E. Rudakovsky, "Radioluminescent crystallophosphors - ionizing radiation detectors", Vestnik of Moscow University, ser.2, Chemistry , 1994, T. 35, N 6, p. 537-541.

 4. T. Nakajima, Y. Murayama, T. Matsuzawa, "Preparation and Dosimetris Propertis of a Highly Sensitive LiF Thermoluminescent Dosimeter", Health Physics. Vol. 36 (January), pp. 79 - 80, Pergamon Press Ltd., 1979. Printed in Great Britain.

 5. T. Nakajima, Y. Murayama, T. Matsuzawa, "Preparation and Dosimetris Propertis of a Highly Sensitive LiF Thermoluminescent Dosimeter", Health Physics. Vol. 36 (January), p. 81, Pergamon Press Ltd., 1979. Printed in Great Britain.

Claims (1)

A method for producing a thermoluminescent ionizing radiation detector based on lithium fluoride, comprising mixing lithium fluoride with copper fluoride, magnesium chloride and ammonium phosphate in water, drying the resulting mixture at 80 ^° C for 4 hours, holding the dried mixture at 1050 ^° C for 30 minutes in a nitrogen atmosphere, cooling the mixture for 30 minutes to 400 ^o C, grinding the obtained thermoluminescent phosphorus, separation of fractions with a degree of dispersion of 80-150 mesh from the ground thermoluminescent phosphorus, its cooling to room temperature temperature, further irradiation with gamma radiation from a source of Co ⁶⁰ and annealing at 250 ^o C for 10 minutes, characterized in that the exposure of the dried mixture for 30 minutes in a nitrogen atmosphere is carried out at a temperature in the range with a lower limit of more than 1050 ^o C, and an upper limit of 1200 ^o C, and after annealing at 250 ^o C for 10 min, the thermoluminescent phosphorus fraction is again cooled to room temperature and further annealed at 150 - 300 ^o C for 0.5 to 3 hours.