2021年云南漾濞MS6.4地震辐射能量的快速测定

doi:10.3969/j.issn.0253-4967.2021.04.011

摘要/Abstract

摘要：

地震辐射能量是表示震源动态特征的物理量, 测定地震辐射能量在地震灾害评估、地震定量化研究和工程地震学研究中具有重要作用。文中利用全球地震台网提供的波形数据, 针对2021年5月21日发生的云南漾濞地震开展了地震辐射能量测定研究工作, 得到的主要结果为: 本次地震的辐射能量为1.6×10¹³J, 能矩比为9.9×10^-6, 低于全球走滑型地震的平均能矩比; 将本次地震与2014年10月7日景谷M_W6.1地震进行对比发现, 虽然2次地震的矩震级相同、震源机制相似、震中仅相距290km, 但景谷地震的能矩比(1.58×10^-5)是本次漾濞地震(9.9×10^-6)的1.6倍; 根据时频分析结果发现, 景谷地震地震波中的高频能量高于漾濞地震。以上结果表明, 漾濞地震属于能量释放效率较低的走滑型地震。相对高频的地震波能量与地震近断层灾害密切相关, 因此我们认为除去震源深度、地质条件和建筑结构的差异外, 较低的能量释放效率是导致这次地震的与同震级的地震相比, 相同烈度的区域面积较小的原因之一。

关键词: 漾濞M_S6.4地震, 辐射能量, 能矩比, 等震线

Abstract:

Radiated seismic energy is a fundamental physical quantity that can be used to represent the dynamic characteristic of the earthquake source, and it is a reliable indicator of the high-frequency component radiated by the seismic source which goes into the seismic waves. Estimating radiated seismic energy has an important role in seismic hazard assessment, quantification of earthquake research, and engineering seismology. Therefore, it is of great significance for the rapid determination of the seismic radiated energy after an earthquake as a reference. After the Yangbi earthquake on May 21, 2021 in Yunnan Province, we measured the radiated seismic energy for the Yangbi earthquake based on the broadband recordings provided by the Global Seismograph Network. The results show that the radiated seismic energy is estimated to be 1.6×10¹³J; the corresponding M_e value is 5.9, which is smaller than M_W; The difference between the single station value and the average value is less than 0.2 units in the determination of energy magnitude for more than 70% of the stations; Based on the results of the seismic moment obtained by Global Centroid Moment Tensor(GCMT), it can be concluded that the energy-moment ratio is 9.9×10^-6, which is considerably weaker than the global average value of (4×10^-5) for the strike-slip earthquakes.

Several previous studies showed that due to the difference in the source rupture process, even earthquakes with small differences in seismic moment and focal mechanism that occurred in the same seismotectonic area may have obviously different amounts of radiated seismic energy. Therefore, we compared this event with Jinggu earthquake that occurred on October 7, 2014. Although the moment magnitudes and focal mechanisms of the two earthquakes are similar, and the epicenter distance is only 290km apart, the area of the same isoseismal for the Jinggu earthquake is significantly larger than the Yangbi earthquake. Earthquake intensity indicates the level of ground shaking, which is associated with the high-frequency components of the seismic waves radiated from the seismic source. Thus, we compared the energy release characteristic of the two earthquakes. The results show that the energy-moment ratio of the Jinggu earthquake(1.58×10^-5)is 1.6 times higher than that of this earthquake(9.9×10^-6); Comparing with the time-domain analysis alone, the time-frequency analysis performed with the S-transform allows us to quantify important details about the source process information provided by the seismic recordings. According to the results of the time-frequency analysis via the S-transform of these two earthquake waves recorded by the same station, the recording of the Jinggu earthquake had much larger spectral amplitudes at frequencies between 0.5 and 1.5Hz during 30~50s after the P-arrival, while this phenomenon was not observed in the Yangbi earthquake. It can be seen that the high-frequency energy of the Jinggu earthquake is higher than that of the Yangbi earthquake.

In summary, the Yangbi earthquake belongs to a low energy release efficiency strike-slip event, the difference in seismic energy radiated per unit seismic moment led to the different area of the same isoseismal. The relatively high-frequency seismic wave is firmly related to the near-fault seismic hazard. Therefore, we suggest that apart from the difference in focal depth, geological condition and building structure, the difference in energy release efficiency is one of the reasons for the different areas of the same isoseismal with the earthquakes that have the same moment magnitude, the low energy release of the Yangbi earthquake limits the capacity to generate enormous numbers of casualties, damage to the environment and critical infrastructure.

Key words: the Yangbi earthquake in Yunnan, radiated seismic energy, energy-moment-ratio, isoseismal

中图分类号:

P315.9

王子博, 刘瑞丰, 孙丽, 李赞, 孔韩东. 2021年云南漾濞M_S6.4地震辐射能量的快速测定[J]. 地震地质, 2021, 43(4): 908-919.

WANG Zi-bo, LIU Rui-feng, SUN Li, LI Zan, KONG Han-dong. THE RAPID DETERMINATION OF RADIATED SEISMIC ENERGY OF M_S6.4 YANGBI EARTHQUAKE[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(4): 908-919.

图/表 8

图1 漾濞MS6.1地震主震附近的地质构造和历史地震分布图红色沙滩球代表漾濞地震, 蓝色圆圈代表历史地震, 断层信息参考常祖峰等(2016b)。 F1维西-乔后-巍山断裂; F2红河断裂; F3兰坪-云龙断裂; F4澜沧江断裂

Fig. 1 The geotectonic and historical earthquake map of the Yangbi earthquake and its adjacent area.

图2 漾濞地震的震中和台站分布图红色五角星代表漾濞地震震中, 黑色三角形代表计算辐射能量所使用的台站

Fig. 2 The epicenter of Yangbi earthquake and distribution of seismic stations.

图3 漾濞地震单台能量震级值与平均值的差及其与震中距的关系

Fig. 3 Distribution of the Me residuals of Yangbi earthquake with distances calculated in this study.

图4 全球浅源走滑地震的地震波辐射能(ER)与地震矩(M0)的对比图辐射能量数据来自IRIS, 地震矩数据来自GCMT; 红色圆点代表景谷地震, 蓝色圆点代表漾濞地震

Fig. 4 Comparison of the radiated seismic energy ER to the seismic moment M0 for the global shallow strike-slip earthquakes.

表1 云南漾濞MW6.1地震和景谷MW6.1地震参数

Table1 Source parameters of the two earthquakes

名称	地震日期 (年-月-日)	震源深度 /km	矩震级	能量震级	辐射能量 /J	能矩比	Ⅷ度区面积 /km²	Ⅵ度区面积 /km²
景谷地震	2014-10-07	5	6.1	6.1	3.0×10¹³	1.58×10^-5	400	9 780
漾濞地震	2021-05-21	8	6.1	5.9	1.6×10¹³	0.99×10^-5	170	5 500

图5 本文选取的恩施台记录景谷地震(a)和漾濞地震(b)的P波到时前10s-到时后50s的速度记录和时频分析图色标棒代表地震波速度记录的对数值

Fig. 5 Waveforms and time-frequency analysis of the two earthquakes, (a)Jinggu earthquake, and(b)Yangbi earthquake.

图6 2014年景谷地震(a)和2021年漾濞地震(b)的余震和烈度分布烈度数据来自云南省地震局烈度图数字化结果; 黑色十字为余震分布, 红色五角星代表主震位置

Fig. 6 Comparison of relocated aftershocks area with isoseismal map of the 2014 Jinggu(a) and the 2021 Yangbi earthquakes.

图7 利用不同方位角的台站测定的辐射能量结果

Fig. 7 The variation of ER determined by stations located in various azimuths.

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