4πβ(PC)-γ符合法测量60Co核素活度及不确定度评定

doi:10.3969/j.issn.1000-1158.2020.11.18

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Abstract The 4Πβ(PC)-γ coincidence method is mainly used to achieve the absolute measurement of β-γ cascade decay radionuclide activity. This method generally measures the VYNS film source sample, This method is usually used to measure the VYNS film source sample, but its preparation process is complicated. This paper simplifies the source process. The source preparation process is optimized. The film source produced by the improved process is measured using a 4Πβ(PC)-γ digital coincidence system. The measurement results obtained by the efficiency extrapolation method show that the apparent efficiency of the new 60Co source reaches 93%, and the specific activity measurement results of the 10 sample sources are consistent within the range of 0.1%. By changing the resolution time, dead time and delay time on the digital compliance software, the influence of the parameter selection on the measurement results is studied, and the uncertainty of the 60Co nuclide activity measurement is evaluated.

Key words： metrology 60Co Nuclide Activity 4Πβ(PC)-&gamma coincidence method absolute measurement source process efficiency extrapolation uncertainty

Received: 03 January 2019 Published: 02 November 2020

PACS:

TB98

Fund:National Key R&D Program of China

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	Articles by authors
	TANG Hao
	FAN Fu-you
	LIANG Jun-cheng
	ZHONG Ke
	ZHU Bao-ji
	YAO Shun-he
	WANG Ren-bo

Cite this article:

TANG Hao,FAN Fu-you,LIANG Jun-cheng, et al. Evaluation of 60Co Nuclide Activity and Uncertainty by 4pβ(PC)-γ Coincidence Method[J]. Acta Metrologica Sinica, 2020, 41(11): 1425-1430.

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http://jlxb.china-csm.org:81/Jwk_jlxb/EN/10.3969/j.issn.1000-1158.2020.11.18 OR http://jlxb.china-csm.org:81/Jwk_jlxb/EN/Y2020/V41/I11/1425

［1］Buckman S M, Ius D. Digital coincidence counting［J］. Nuclear Instruments & Methods in Physics Research, 1996, 369(2-3): 368-374.
［2］Park T S, Han Y H, Lee J M. An improved coincidence counting technique for standardization of radionuclides［J］. Applied Radiation & Isotopes, 1998, 49(9-11): 1147-1151.
［3］Havelka M, Auerbach P, Sochorová J. Software coincidence counting［J］. Applied Radiation & Isotopes, 2002, 56(1-2): 265-268.
［4］Havelka M, Auerbach P, Sochorová J. Application of pulse mixing method in software coincidence counting［J］. Applied Radiation & Isotopes, 2004, 60(2): 409-413.
［5］Chernyshev V I, Korostin S V, Martynyuk Y N, et al. A digital coincidence method［J］. Measurement Techniques, 2004, 47(12): 1204-1210.
［6］Keightley J, Park T S. Digital coincidence counting for radionuclide standardization［J］. Metrologia, 2007, 44(4): S32.
［7］Zhang M, Yao S, Liang J, et al. Standardization of the radionuclides 60Co and 59Fe by digital 4Πβ(PC)-γ(NaI) coincidence counting［J］. Applied Radiation & Isotopes, 2016, 109(4): 341-344.
［8］Baerg A P. The efficiency extrapolation method in coincidence counting［J］. Nucl Instrum Methods, 1973, 112(1-2):143-150.
［9］Lowenthal G C, Wyllie H A. Thin 4p sources on electrosprayed ion exchange resin for radioactivity standardization［J］. International Journal of Applied Radiation & Isotopes, 1973, 24(7): 415-418.
［10］陈庆江, 杨景霞. 电喷涂硅胶薄层底衬制备4Πβ薄膜源［J］. 原子能科学技术, 1980, 14(1): 128.
Chen Q J, Yang J X. Preparation of 4Πβ film source by electrospraying silica thin layer underlayer［J］. Atomic Energy Science and Technology, 1980, 14(1): 128.

［11］种培基, 贺先运. 电喷硅溶胶衬垫制备4Π薄膜源［J］. 原子能科学技术, 1980, 14(1): 125-125.
Zhong P J, He X Y. Preparation of 4Πβ film source by electrospraying silica thin layer underlayer［J］. Atomic Energy Science and Technology, 1980, 14(1): 125.

［12］仇九子, 王书志. NaI(Tl)-HPGeγ-γ符合谱仪系统死时间校正方法［J］. 核电子学与探测技术, 1996,(3): 232-234.
Qiu J Z, Wang S Z. NaI(Tl)-HPGeγ-γ conforms to the spectrometer system dead time correction method［J］. Nuclear Electronics and Detection Technology, 1996,(3): 232-234.
［13］李谋, 代义华, 倪建忠. 符合法原理及其在活度测量中的应用［J］. 原子能科学技术, 2008, 42(3): 223-226.
Li M, Dai Y H, Ni J Z. Principle of conformity and its application in activity measurement［J］. Atomic Energy Science and Technology, 2008, 42(3): 223-226.

［14］阎春光. β-γ道相对延迟时间测定［J］. 原子能科学技术, 1994, 28(5): 465-470.
Yan C G. Determination of relative delay time of β-γ channel［J］. Atomic Energy Science and Technology, 1994, 28(5): 465-470.

［15］吴学周, 王载勇, 杨元弟. 4Πβ(PC)-γ符合测量60Co活度［J］. 核电子学与探测技术, 1986,(3): 36-39.
Wu X Z, Wang Z Y, Yang Y D. 4Πβ(PC)-γ conforms to the measurement of 60Co activity［J］. Nuclear Electronics and Detection Technology, 1986,(3): 36-39.
［16］Kossert K, Marganiecgalazka J, Mougeot X, et al. Activity determination of 60Co and the importance of its beta spectrum［J］. Applied Radiation & Isotopes, 2017, 134(6):162-165.
［17］陈凌峰. 标准不确定度A类评定中极差法的深入讨论［J］. 计量学报, 2019, 40(2):347-352.
Chen L F. In-depth discussion of the range method in the standard uncertainty evaluation of type A［J］. Acta Metrologica Sinica, 2019, 40(2):347-352.