地震监测氡观测仪器校准新方法研究

地震 ›› 2016, Vol. 36 ›› Issue (3): 46-54.

地震监测氡观测仪器校准新方法研究

任宏微^1,2, 姚玉霞³, 黄仁桂⁴, 陈兰庆⁵, 王桂清⁶

1.中国地震局地壳应力研究所(地壳动力学重点实验室), 北京 100085;
2.中国地震局地球物理研究所, 北京 100081;
3.甘肃省地震局平凉中心地震台, 甘肃平凉 744000;
4.江西地震局九江地震台, 江西九江 332005;
5.甘肃省地震局, 甘肃兰州 730000;
6.中国地震台网中心, 北京 100045

收稿日期:2016-02-17 发布日期:2020-07-03
通讯作者: 姚玉霞, 工程师, E-mail: yaoyuxia999888@163.com
作者简介:任宏微(1984-), 女, 山东莱州人, 博士研究生, 助理研究员, 主要从事地震地下流体氡观测方法、氡前兆机理研究。
基金资助:
中国地震局地壳应力研究所中央级公益性科研院所基本科研业务专项(ZDJ2014-05);公益性行业科研专项(201408008); 中国地震局三结合项目(15280x)

A New Calibration Method of Emanometer in Earthquake Monitoring

REN Hong-wei^1,2, YAO Yu-xia³, HUANG Ren-gui⁴, CHEN Lan-qing⁵, WANG Gui-qing⁶

1. Key Laboratory of Crustal Dynamics, Institute of Crustal Dynamics, CEA, Beijing 100085 China;
2. Institute of Geophysics, CEA, Beijing 100081 China;
3. Pingliang Central earthquake Station, Gansu Earthquake Administration, Gansu Pingliang, 744000 China;
4. Jiujiang Earthquake Station, Jiangxi Earthquake Administration, Jiangxi Jiujiang, 332005, China;
5. Gansu Earthquake Administration, Gansu Lanzhou 730000, China;
6. China Earthquake Networks Center,Beijing 100045, China

Received:2016-02-17 Published:2020-07-03

摘要/Abstract

摘要： 利用国际刻度参考装置AlphaGUARD测氡仪及水氡测量组件, 使用水中溶解氡(或豁免级氡气源), 开展代替目前氡气固体源校准方法实验。对FD-125测氡仪标配的3个闪烁室(1#、 3#及5#)分别使用水中溶解氡和氡气固体源进行校准实验, 3个闪烁室的校准K值相对误差分别为5.06%, 1.92%及2.76%, 可以达到目前地震监测氡观测技术要求。实验结果表明, 水中溶解氡代替氡气固体源校准, 可以解决目前氡气固体源校准中存在的运输困难、维修技术要求高等问题, 是今后氡观测仪器校准技术的发展趋势。

关键词: 氡气固体源校准, 水中溶解氡校准, 闪烁室, FD-125测氡仪, AlphaGUARD测氡仪

Abstract: By using AlphaGUARD radon measurement instrument, the international calibration reference device, we carried out a dissolved radon calibration experiment to replace the general calibration by solid source of radon gas. The three scintillation chambers (1 #, 3 # and 5 #) of FD-125 emanometer are calibrated respectively, and then are compared with the results of using solid source of radon gas. The results show that the error of k value using “dissolved radon calibration” relative to using solid source of radon gas were respectively 5.06%, 1.92% and 2.76%. The above results indicate that the newly developed calibration method instead of traditional solid source of radon gas accords with the radon observation technology requirement in earthquake monitoring system, and can solve difficulty in transportation and high technical maintenance requirements in the calibration using solid source of radon gas. It is the trend of radon calibration technology development in the future.

Key words: FD-125 emanometer, AlphaGUARD emanometer, Scintillation chamber, Radon source calibration

中图分类号:

P315.72

任宏微, 姚玉霞, 黄仁桂, 陈兰庆, 王桂清. 地震监测氡观测仪器校准新方法研究[J]. 地震, 2016, 36(3): 46-54.

REN Hong-wei, YAO Yu-xia, HUANG Ren-gui, CHEN Lan-qing, WANG Gui-qing. A New Calibration Method of Emanometer in Earthquake Monitoring[J]. EARTHQUAKE, 2016, 36(3): 46-54.

参考文献

[1] 李宣瑚. 唐山地震前京津地区水氡异常场的某些特征[J]. 地震地质, 1987, 4(1): 57-66.
[2] 张炜, 邢玉安, 邢如英. 地下水中氮含量离散度变化与地震的短临前兆[J]. 地震学报, 1986, 9(3): 312-318.
[3] 杜学彬, 张新基, 张慧. 中国大陆地震水氡短临异常的空间特征研究[J]. 地震学报, 1996, 18(6): 358-364.
[4] Crockett R G M, Gillmore G K, Phillips P S, et al. Radon anomalies preceding earthquakes which occurred in the UK, in summer and autumn[J]. Science of the Total Environment, 2002, 364: 138-148.
[5] Tom Kuo M C, Fan K, Kuochen H, et al. A Mechanism for anomalous decline in radon precursory to an earthquake [J]. Ground water, 2006, 44(5): 642-647.
[6] Erees F S, Aytas S, Sac M M, et al. Radon concentrations in thermal waters related to seismic events along faults in the Denizli Basin, Western Turkey[J]. Radiation Measurements, 2007, 42(1): 80-86.
[7] 刘耀炜, 任宏微. 汶川8.0 级地震氡观测值震后效应特征初步分析[J]. 地震, 2009, 29(1): 121-131.
[8] Ren H W, Liu Y W, Yang D Y. A preliminary study of post-seismic effects of radon following the M_S8.0 Wenchuan earthquake[J]. Radiation Measurements, 2012, 47(1): 82-88.
[9] 李彤起, 李正蒙, 陈兰庆, 等. 测氡仪器固体氡气源标定新技术推广应用进展与效益[J]. 西北地震学报, 1997, 19(4): 71-77.
[10] 张清秀, 孔令昌, 江劲军, 等. 新型流气式固体氡源用于氡仪器标定的实验研究[J]. 华南地震, 2012, 32(2): 60-67.
[11] 杜文勇, 贺永忠. GD-L2型流气式固体氡源标定数字化气氡仪的经验探讨[J]. 防灾减灾学报, 2013, 29(2): 40-44.
[12] Birchard G F, Libby W F. Soil radon concentration changes preceding and following four magnitude 4.2～4.7 earthquakes on the San Jacinto Fault in southern California[J]. Journal of Geophysical Research, 1980, 85(B6): 3100-3106.
[13] Iakovleva V S, Ryzhakova N.K. Spatial and temporal variations of radon concentration in soil air[J]. Radiation Measurements, 2003, 36(1-3): 385-388.
[14] Tsukuda T. Radon gas monitoring by gamma-ray measurements on the ground for detecting crustal activity changes-preliminary study by repeat survey method[J]. Bulletin of the Earthquake Research Institute, 2008, 83: 227-241.
[15] Fabio Vizzini, Maria Brai. In-soil radon anomalies as precursors of earthquakes: a case study in the SE slope of Mt. Etna in a period of quite stable weather conditions[J]. Journal of Environmental Radioactivity, 2012, 113: 131-141.
[16] Jaishi H P, Singh S, Tiwari R P, et al. Temporal variation of soil radon and thoron concentrations in Mizoram (India), associated with earthquakes[J]. Natural Hazards, 2014, 72(2): 443-454.
[17] Noguchi M, Wakita, H. A method for Continuous Measurement of Radon in Groundwater for. Earthquake Prediction[J]. Journal of Geophysical Research, 1977, (82): 1353-1359.
[18] Singh M, Kumar M, Jain R K, et al. Radon in ground water related to seismic events[J]. Radiation Measurements, 1999, 30(4): 465-470.
[19] Plastino W, Bella F. Radon groundwater monitoring at underground Laboratory of Gran Sasso[J]. Geophysical Research Lett, 2001, 28: 2675-2680.
[20] Dean J C J, Burke M. A second intercomparison of 222Rn measurement systems in European laboratories[J]. Applied Radiation & Isotopes, 1996, 47(s9-10): 835-840
[21] 孟冶成, 周剑良, 潘佳林, 等. 闪烁室和电离室法测氡的气压效应[J]. 现代电子技术, 2007, 247(8): 181-185.
[22] Wojcik M. Procedure for the Measurement of the Radon Concentration in Natural Gas[M]. Brunswick, 1983.