2015年尼泊尔MW7.8地震前磁扰动极化异常特征分析

doi:10.3969/j.issn.0253-4967.2021.05.016

摘要/Abstract

摘要：

文中基于中国大陆地区48个台站的地磁秒值资料, 采用极化法对2015年尼泊尔M_W7.8地震前的磁扰动特征进行了分析。极化法的逐步计算结果与地磁K指数的对比分析表明极化高值异常与空间磁场活动之间没有相关性, 可用于提取震磁异常信息。距震中1 500km范围内台站的极化值在震前98d出现了同步性高值异常, 考虑到磁场变化具有区域同步性, 提出了极化逐日相关分析。研究发现地震孕育过程中各台站间的极化相关性明显增强, 而地震发生在同步性转折阶段。基于极化值相对变化量进行的空间异常分析显示, 尼泊尔地震前 >20% 的台站出现持续3d以上的异常, 且具有明显的区域性特征。文中从构造动力演化角度对地磁极化异常的孕育和发展进行了解释, 对磁场变化机理进行更进一步的探索。研究认为, 多台同步性极化异常和逐日相关转折对强震具有重要的指示意义, 该成果能为强震监测预测提供新的技术途径。

关键词: 地震地磁, 极化法, 尼泊尔M_W7.8地震, 逐日相关

Abstract:

On April 25, 2015, a strong earthquake with magnitude 7.8(M_W)and focal depth of 8.2km(according to USGS)occurred in Nepal(28.15°N, 84.71°E), which caused heavy casualties and property losses to Nepal, China, and some neighboring countries. The focal mechanism solution shows that the earthquake is a low-angle thrust earthquake, resulting from the collision and following long-term compression between the Indian Plate and Eurasian Plate. In this paper, we analyze the magnetic disturbance characteristics before the Nepal M_W7.8 earthquake using polarization method based on the geomagnetic second data of 48 stations in mainland China.
Polarization method uses the ratio of the vertical component(Z)to the horizontal component(H)of the geomagnetic field, i.e. Z/H. This method can suppress external interference and thus extract seismo-magnetic anomaly information. Previous geophysical studies have shown that the perturbation in geomagnetic field during the earthquake preparation has a far greater impact on Z than H. The high polarization anomaly may contain some magnetic field information related to earthquake preparation. The calculation of geomagnetic second data includes three main parts: spectrum analysis, polarization calculation and abnormal signal extraction. The dominant frequency band(0.01~0.2Hz)is selected for subsequent calculation and analysis.
(1)By analyzing the relationship between the polarization and the perturbation in the geomagnetic field through spectrum analysis, we find that the polarization value at each stage is obviously negatively correlated with the geomagnetic K index, indicating that the high polarization anomaly is almost not related to the geomagnetic activity and therefore can be used to analyze the pre-seismic anomaly. In order to ensure the reliability of the calculation results, it is recommended that the data length should exceed 1 year, based on the annual variation characteristics of polarization value.
(2)The polarization value of the Lhasa station(epicentral distance of 628km)and the Shiquanhe station(epicentral distance of 652km)had risen for 3 days before the Nepal earthquake, and the anomaly amplitude of the Lhasa station, which is closer to the epicenter, is significantly higher than that of the Shiquanhe station. We analyze the polarization value of stations within 1 500km from the epicenter of the Nepal earthquake, which reveals a synchronous increase of polarization value starting about 98 days before the earthquake. Considering the regional synchronization of the perturbation in the geomagnetic field, a daily correlation analysis method is proposed to analyze the polarization of stations within 1 500km from the epicenter. We find that there is a significant increase in polarization correlation during earthquake preparation, and the earthquake occurred at the synchronization transition phase. It is suggested that the synchronization may be attributed to the additional effect of the source field associated with earthquake on the regional geomagnetic field. Certainly, this method requires higher data quality, and some certain interference factors need to be eliminated to reduce the influence of individual data on the overall results.
(3)The pre-seismic magnetic disturbance changes of each station are different in anomaly amplitude, which is associated with the spatial position, tectonic setting, and signal source of the abnormality. Subsequently, spatial analysis based on the relative variation of polarization value is necessary. The results show that continuous polarization anomalies exceeding 3 days before the earthquake occurred in more than 20% of stations, the spatial scope and abnormal amplitude experience a change trend from increasing to reducing, however, the spatial distribution of anomalies which has obvious regional characteristics always revolves around the epicenter. The time-space changing process of polarization anomalies really reflects the dynamic changes of the regional geomagnetic field, which is the result of external influence with strong dynamic characteristics. Plate movement is the main driving force of the perturbation in the regional geomagnetic field, while a large amount of melting fluid substances provide good channel for preparation and propagation of geomagnetic field. Thus, the generation and distribution of polarization anomalies are closely related to the geodynamic evolution of geological structures. Stress accumulation caused by geological activities is the main reason for the perturbation in the geomagnetic field.
(4)The study suggests that multiple synchronous polarization abnormality and turning in daily correlation have important indications for strong earthquakes, which will provide a new approach for monitoring and prediction. However, the quantitative relationship between anomaly amplitude and epicentral distance is not obvious, which is affected by tectonic environment of station, seismogenic background, complexity of changes of spatial geomagnetic field and fewer seismic examples. Therefore, in order to obtain more evidence and improve reliability, more seismic examples and theoretical analysis is necessary.

Key words: seismogeomagnetism, polarization, the Nepal M_W7.8 earthquake, daily correlation

中图分类号:

P315.72⁺1

管贻亮, 董晓娜, 尹玉振, 冯丽丽, 殷海涛. 2015年尼泊尔M_W7.8地震前磁扰动极化异常特征分析[J]. 地震地质, 2021, 43(5): 1311-1325.

GUAN Yi-liang, DONG Xiao-na, YIN Yu-zhen, FENG Li-li, YIN Hai-tao. PRE-SEISMIC POLARIZATION CHARACTERISTICS OF MAGNETIC DISTURBANCE OF THE 2015 M_W7.8 NEPAL EARTHQUAKE[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(5): 1311-1325.

图/表 10

图 1 参与计算的地磁观测台站空间分布

Fig. 1 The spatial distribution of geomagnetic observation stations used in the calculation.

图 2 拉萨台2015—2017年极化各阶段的计算结果 a 地磁K指数日值曲线; b 垂直分量频谱曲线; c水平分量频谱曲线; d 极化值日值曲线与富氏拟合曲线;e 5日滑动极化值与5日滑动K指数对比曲线

Fig. 2 The polarization calculation results of each stage of Lasa station from 2015 to 2017.

图 3 极化值计算流程

Fig. 3 The flow chart of polarization calculation.

图 4 拉萨台的极化结果与地磁K指数曲线对比图 a GM4仪器计算的极化值; b M15仪器计算的极化值; c 拉萨台的地磁K指数

Fig. 4 The comparison chart of polarization results and K index of Lhasa station.

图 5 狮泉河台的极化结果与地磁K指数曲线对比图 a GM4仪器计算的极化值; b M15仪器计算的极化值; c 狮泉河台的地磁K指数

Fig. 5 The comparison chart of polarization results and K index of Shiquanhe station.

图 6 5日滑动平均极化结果 a 拉萨台GM4仪器; b 拉萨台M15仪器; c 狮泉河台GM4仪器; d 狮泉河台M15仪器

Fig. 6 The polarization results of 5-day moving average.

图 7 尼泊尔MW7.8地震前震中附近台站的极化异常时序图道孚台(a)、肃北台(b)、格尔木台(c)、都兰台(d)、喀什台(e)和且末台(f)2015年的滑动平均极化结果

Fig. 7 The timing chart of polarization abnormality of nearby stations before the Nepal MW7.8 earthquake.

图 8 台站间逐日滑动相关曲线拉萨台(a)、狮泉河台(b)、肃北台(c)、格尔木台(d)、喀什台(e)和且末台(f)分别与其余5个台站的逐日滑动相关曲线

Fig. 8 The daily correlation curve between the individual stations.

图 9 台站间逐日滑动相关均值曲线拉萨台(a)、狮泉河台(b)、肃北台(c)、格尔木台(d)、喀什台(e)和且末台(f)分别与其余5个台站的逐日滑动相关均值曲线

Fig. 9 The daily mean correlation curve between the individual stations.

图 10 极化逐日空间异常分布图 a 2015年1月17日极化异常空间分布图; b 2015年1月18日极化异常空间分布图;c 2015年1月19日极化异常空间分布图

Fig. 10 The spatial distribution map of polarization abnormality.

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