地电阻率日变化成因分析

doi:10.3969/j.issn.0253-4967.2019.06.010

摘要/Abstract

摘要： 中国部分长期连续观测的地电阻率台站的观测数据呈现出清晰的日变化形态，依据单一测道的变化特征，日变化可分为2类相反的形态：一类观测数据白天下降夜间上升；另一类则白天上升夜间下降。文中结合含水岩土介质电阻率的影响因素、台站电性结构和地电阻率影响系数理论，分析认为固体潮引起的介质电阻率变化幅度太小，以目前地电阻率观测仪器的分辨率还不足以记录到固体潮的影响，地电阻率的日变化主要由昼夜温差所引起。昼夜温差将使浅层介质电阻率发生大幅度的昼降夜升变化，对于浅层介质影响系数为正的测道，其日变化呈现昼降夜升的形态，而浅层介质影响系数为负的测道，其日变化则呈现出昼升夜降的形态。

关键词: 地电阻率, 日变化, 成因机理, 温度, 固体潮

Abstract: Parts of the consecutive apparent resistivity monitoring stations of China have recorded clear diurnal variations. The relative amplitudes of diurnal variations at these stations range from 1.3‰ to 5.8‰. The daily accuracies of apparent resistivity observation are better than 1‰, because the background electromagnetic noise is rather low at these stations. Therefore, the diurnal variations of apparent resistivity recorded at these stations are real phenomena. The diurnal variation shapes can be divided into two opposite types according to their characteristics. One type is that the apparent resistivity data decreases during the daytime but increases during the nighttime(Type 1). The other type is the apparent resistivity data increases during the daytime but decreases during the nighttime(Type 2). There is a correspondence between the diurnal and annual variation patterns of apparent resistivity. For the monitoring direction with diurnal variation of Type 1, the apparent resistivity decreases in summer and increases in winter. However, for the monitoring direction with diurnal variation of Type 2, the apparent resistivity increases in summer and decreases in winter.
We take an analysis on the mechanism of apparent resistivity diurnal variation, combining the influence factors of water-bearing medium's resistivity, the electric structure of stations, and the apparent resistivity sensitivity coefficient(SC)theory. Intuitively, diurnal variation of apparent resistivity is caused by diurnal variation of medium resistivity in the measured area. The diurnal variation of medium resistivity will inevitably be caused by the factors with diurnal variation. Among the possible factors, there is diural variation in earth tide and temperature.
Our analysis displays that apparent resistivity diurnal variation is not caused by the usually-believed earth tide, but by the ground temperature difference between daytime and nighttime. The earth tide strain is too small to cause remarkable effects on the apparent resistivity data. On the other hand, the daily tide strain has two peak-valley variations, and its phase and amplitude has a period of approximate 28 days. However, the apparent resistivity data do not show these corresponding features to earth tide. Furthermore, the detection range of current apparent resistivity stations is within a depth of several hundred meters. Within this depth range, the medium deformation caused by solid tide can be regarded as uniform change. Therefore, all monitoring directions and all stations will have the same pattern of diurnal variation.
In general, the temperature increases in the daytime but decreases in the nighttime. For most water-bearing rock and soil medium, its resistivity decreases as temperature increases and increases as temperature decreases. Diurnal temperature difference affects about 0.4m of soil depth. Therefore, resistivity of this surface thin soil layer decreases in the daytime while increases in the nighttime. Under layered medium model, SC of each layer represents its contribution to the apparent resistivity. For the stations with positive SC of surface layer, apparent resistivity decreases in the daytime but increases in the nighttime. While for the stations with negative SC of surface layer, apparent resistivity diurnal variations display the opposite shape.

Key words: apparent resistivity, diurnal variation, mechanism, temperature, earth tide

中图分类号:

P315.72⁺2

解滔, 卢军, 闫伟. 地电阻率日变化成因分析[J]. 地震地质, 2019, 41(6): 1464-1480.

XIE Tao, LU Jun, YAN Wei. THE MECHANISM OF DIURNAL VARIATION IN CONSECUTIVE APPARENT RESISTIVITY OBSERVATION[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(6): 1464-1480.

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