AFTERSHOCK PROBABILISTIC FORECASTING AND TESTING OF OPERABILITY IN EARTHQUAKE FIELD INVESTIGATION ON-SITE: A CASE OF THE 2025 DINGRI MS6.8 EARTHQUAKE IN XIZANG

doi:10.3969/j.issn.0253-4967.2025.03.20250028

Abstract

Abstract:

On January 7, 2025, a M_S6.8 earthquake struck Dingri, Xizang, causing significant economic losses and casualties. In response, the China Earthquake Administration launched a multidisciplinary scientific investigation, among which the analysis of sequence characterization and the probability forecasting of large aftershocks is an important and meaningful part of the work. This study aims to enhance the understanding of the aftershock sequence and provide timely scientific support for field investigations. To achieve this, we employ a temporal Epidemic-Type Aftershock Sequence(ETAS)model to perform a real-time tracking analysis of the aftershock sequence over the first seven days following the mainshock. The temporal ETAS model was employed to analyze the evolving characteristics of the aftershock sequence at 0.1-day intervals, and short-term aftershock probability forecasts were generated for the subsequent one-day period. Model performance was evaluated using the Brier Score, a metric that quantifies the agreement between probabilistic forecasts and observed aftershock occurrences. The evaluation focused on different magnitude thresholds to assess the consistency and predictive skill of the model.

Key findings from our study include: 1)The fitting of ETAS model to observed aftershock activity was generally consistent with reality. The fitted model parameters suggest that the overall decay rate of aftershocks aligns closely with typical sequence decay behaviors(p=1.06). Moreover, the proportion of triggered ‘offspring’ events within the sequence is relatively low(α=1.58), indicating that off-spring events did not heavily dominate the primary aftershock activity. The model’s fitting results are consistent with the observed seismic sequence, except for a slight deviation identified around the 220th aftershock, where the observed activity exceeds the expectation based on a homogeneous Poisson process. 2)A time-tracking analysis of the model parameters across varying magnitude thresholds reveals that the parameter estimates begin to stabilize approximately 2.8 days after the mainshock. This suggests that incomplete aftershock recordings during the early phase can impact the reliability of early parameter estimation. Thus, early-stage catalog incompleteness should be carefully accounted for in operational forecasting models. 3)The model also demonstrates high sensitivity to the occurrence of strong aftershocks. When such events occur, they are quickly reflected in the intensity and frequency curves, demonstrating the model’s potential and strong applicability for short-term aftershock forecasting, particularly in a science-based emergency response context. 4)Brier score evaluation further supports the model’s forecasting effectiveness. For aftershocks above magnitude 3.5, 4.0, and 5.0, the forecasting performance consistently exceeds that of a random forecast baseline. Although the model underperforms slightly in forecasting aftershocks above magnitude 4.5 in the early stages, its performance improves over time, especially for magnitude 4.5 and 5.0 events, indicating increasing skill as more data accumulates. These findings highlight the potential of integrating Brier Score evaluation into the temporal ETAS model for assessing probabilistic aftershock forecasts.

The results demonstrate that the ETAS model provides valuable operational forecasting capabilities for guiding scientific investigations and emergency response following major earthquakes. The study also identifies key challenges for future improvements, including data completeness, parameter stability, and model adaptability to complex sequences of aftershocks. Moving forward, further refinement of hybrid forecasting approaches—integrating multiple models based on statistical and physics-based methods—could enhance the accuracy and reliability of short-term aftershock forecasting. The operational feasibility of the ETAS model, combined with rigorous evaluation metrics, underscores its role in advancing earthquake forecasting methodologies and supporting earthquake disaster risk reduction in China and beyond.

Key words: Xizang M_S6.8 Dingri earthquake, operational earthquake forecasting, epidemic-type aftershock-sequences model, probability forecasting, performance evaluation

摘要：

2025年1月7日发生的西藏定日6.8级地震对当地经济和群众生命造成了重大灾害。震后, 中国地震局围绕此次地震, 采用不同学科手段开展了跟踪式分析的科考工作, 其中序列特征分析和震后余震概率预测分析是一项重要且有意义的工作内容。为增进对此次地震序列的认识并及时为科考工作提供支撑, 文中针对震后7.1d已经积累的余震序列数据, 采用时间ETAS模型, 以0.1d为间隔进行了跟踪式分析, 对未来1d进行余震短期概率预测, 并使用描述概率预测结果与实际观测一致性的Brier评分方法对模型效能进行检验, 获得以下主要认识: 1)余震序列整体呈现贴近正常水平的衰减速率(p=1.06), 触发产生的“子事件”比例不高(α=1.58), 模型整体拟合情况与余震实际发生情况基本一致; 2)模型参数从震后第2.8d开始趋于稳定, 震后短时间内余震记录不全的问题会对模型拟合产生影响; 3)该模型的预测曲线能够快速反映第6.5d发生的5.0级余震情况, 显示出该模型对此类工作中余震短期预测较强的适应性和应用的潜在价值; 4)针对以上跟踪式分析预测结果的Brier评分结果显示, 该模型对3.5级、 4.0级和5.0级以上余震的预测优于随机预测(score<0.25), 其中对4.5级和5.0级以上余震的预测效能随时间不断提升。文中探讨了将Brier评分方法应用于时间ETAS模型概率预测效能评估中的潜力, 发现其在综合评估预测表现及预测能力随时间变化方面具有较大优势, 该模型的可操作性预测框架对支撑地震科学考察和辅助地震决策具有重要价值, 同时讨论了下一步开展此类工作需要解决的潜在问题。

关键词: 西藏定日M_S6.8地震, 可操作的地震预测, 传染型余震序列模型, 余震概率预测, 效能检验

ZHANG Sheng-feng, ZHANG Yong-xian. AFTERSHOCK PROBABILISTIC FORECASTING AND TESTING OF OPERABILITY IN EARTHQUAKE FIELD INVESTIGATION ON-SITE: A CASE OF THE 2025 DINGRI M_S6.8 EARTHQUAKE IN XIZANG[J]. SEISMOLOGY AND GEOLOGY, 2025, 47(3): 835-849.

张盛峰, 张永仙. 针对地震科考工作的可操作性余震概率预测及检验——以西藏定日 M_S6.8 地震为例[J]. 地震地质, 2025, 47(3): 835-849.

Figures/Tables 7

Fig. 1 Epicenter distribution of aftershock sequence of MS6.8 earthquake in Dingri, Xizang.

Fig. 2 Different analysis perspectives on the MS6.8 earthquake sequence in Dingri, Xizang, carried out during this research work.

Fig. 3 The results of model fitting and residual analysis of the aftershock sequence of the Dingri MS6.8 earthquake in Xizang using the temporal ETAS model.

Table 1 Parameters used in the short-term probabilistic forecasting model of the temporal ETAS model

拟合起始时刻C₀	时间步长	震级下限M_C	预测时长	目标震级	初始模型参数/最终结果
0.063d	0.1d	2.6、3.0、0.1	未来1d	3.5、5.0、0.5	μ=0.01/6.72
					k=0.05/0.04
					c=0.5/0
					α=1.28/1.58
					p=1.25/1.06

Fig. 4 Variation of model parameters over time obtained from trace-based analysis of the earthquake sequence in Dingri, Xizang.

Fig. 5 The aftershock probability and occurrence rate of the MS6.8 earthquake in Dingri, Xizang calculated using temporal ETAS model.

Fig. 6 Brier score test for the temporal ETAS model for short-term probability forecasting of aftershocks for the MS6.8 earthquake in Dingri, Xizang.

References 39

[1]	蒋长胜, 韩立波, 郭路杰. 2014. 新疆于田地区2008年以来3个地震序列的参数早期特征[J]. 地震学报, 36(2): 165-174.
	JIANG Chang-sheng, HAN Li-bo, GUO Lu-jie. 2014. Parameter characteristics in the early period of three earthquake sequences in the Yutian, Xinjiang since 2008[J]. Acta Seismologica Sinica, 36(2): 165-174 (in Chinese).
[2]	蒋长胜, 吴忠良, 韩立波, 等. 2013. 地震序列早期参数估计和余震概率预测中截止震级M_C的影响: 以2013年甘肃岷县-漳县6.6级地震为例[J]. 地球物理学报, 56(12): 4048-4057.
	JIANG Chang-sheng, WU Zhong-liang, HAN Li-bo, et al. 2013. Effect of cutoff magnitude M_C of earthquake catalogues on the early estimation of earthquake sequence parameters with implication for the probabilistic forecast of aftershocks: The 2013 Minxian-Zhangxian, Gansu, M_S6.6 earthquake sequence[J]. Chinese Journal of Geophysics, 56(12): 4048-4057 (in Chinese).
[3]	Akaike H. 1974. A new look at the statistical model identification[J]. IEEE Transactions on Automatic Control, 19(6): 716-723.
[4]	Akaike H. 1998. Information theory and an extension of the maximum likelihood principle[G]// Parzen E, Tanabe K, Kitagawa G(Eds.), Selected Papers of Hirotugu Akaike. Springer New York, NY: 199-213.
[5]	Brier G W. 1950. Verification of forecasts expressed in terms of probability[J]. Monthly Weather Review, 78(1): 1-3.
[6]	Daley D J, Vere-Jones D. 2003. An Introduction to Theory of Point Processes-Volume 1: Elementary Theory and Methods(2nd Edition)[M]. Springer-Verlag New York, NY.
[7]	Gerstenberger M C, Wiemer S, Jones L M, et al. 2005. Real-time forecasts of tomorrow’s earthquakes in California[J]. Nature, 435(7040): 328-331.
[8]	Gutenberg B, Richter C F. 1944. Frequency of earthquakes in California[J]. Bulletin of the Seismological Society of America, 34(4): 185-188.
[9]	Iwata T. 2008. Low detection capability of global earthquakes after the occurrence of large earthquakes: Investigation of the Harvard CMT catalogue[J]. Geophysical Journal International, 174(3): 849-856.
[10]	Jordan T H. 2013. Lessons of L'Aquila for operational earthquake forecasting[J]. Seismological Research Letters, 84(1): 4-7.
[11]	Jordan T H, Jones L M. 2010. Operational earthquake forecasting: Some thoughts on why and how[J]. Seismological Research Letters, 81(4): 571-574.
[12]	Jordan T H, Marzocchi W, Michael A J, et al. 2014. Operational earthquake forecasting can enhance earthquake preparedness[J]. Seismological Research Letters, 85(5): 955-959.
[13]	Kawamura M, Chen C C. 2013. Precursory change in seismicity revealed by the Epidemic-Type Aftershock-Sequences model: A case study of the 1999 Chi-Chi, Taiwan earthquake[J]. Tectonophysics, 592: 141-149.
[14]	Lewis P A W, Shedler G S. 1979. Simulation of nonhomogeneous poisson processes by thinning[J]. Naval Research Logistics Quarterly, 26(3): 403-413.
[15]	Mizrahi L, Dallo I, van der Elst N J, et al. 2024. Developing, testing, and communicating earthquake forecasts: Current practices and future directions[J]. Reviews of Geophysics, 62(3): e2023RG000823.
[16]	Molchan G M, Dmitrieva O E, Rotwain I M, et al. 1990. Statistical analysis of the results of earthquake prediction, based on bursts of aftershocks[J]. Physics of the Earth and Planetary Interiors, 61(1-2): 128-139.
[17]	Ogata Y. 1978. The asymptotic behaviour of maximum likelihood estimators for stationary point processes[J]. Annals of the Institute of Statistical Mathematics, 30(2): 243-261.
[18]	Ogata Y. 1981. On Lewis’ simulation method for point processes[J]. IEEE Transactions on Information Theory, 27(1): 23-31.
[19]	Ogata Y. 1988. Statistical models for earthquake occurrences and residual analysis for point processes[J]. Journal of the American Statistical Association, 83(401): 9-27.
[20]	Ogata Y. 1989. Statistical model for standard seismicity and detection of anomalies by residual analysis[J]. Tectonophysics, 169(1): 159-174.
[21]	Ogata Y. 1992. Detection of precursory relative quiescence before great earthquakes through a statistical model[J]. Journal of Geophysical Research: Solid Earth, 97(B13): 19845-19871.
[22]	Ogata Y. 2001. Increased probability of large earthquakes near aftershock regions with relative quiescence[J]. Journal of Geophysical Research: Solid Earth, 106(B5): 8729-8744.
[23]	Ogata Y. 2006. Monitoring of anomaly in the aftershock sequence of the 2005 earthquake of M7.0 off coast of the western Fukuoka, Japan, by the ETAS model[J]. Geophysical Research Letters, 33(1): L01303.
[24]	Ogata Y, Tsuruoka H. 2016. Statistical monitoring of aftershock sequences: A case study of the 2015 M_W7.8 Gorkha, Nepal, earthquake[J]. Earth, Planet and Space, 68(1): 44.
[25]	Omi T, Ogata Y, Hirata Y, et al. 2014. Estimating the ETAS model from an early aftershock sequence[J]. Geophysical Research Letters, 41(3): 850-857.
[26]	Omori F. 1894. On the aftershocks of earthquakes[J]. Journal of the College of Science, Imperial University of Tokyo, 7: 111-200.
[27]	Papangelou F. 1972. Integrability of expected increments of point processes and a related random change of scale[J]. Transactions of the American Mathematical Society, 165: 483-506.
[28]	Reasenberg P A, Jones L M. 1989. Earthquake hazard after a mainshock in California[J]. Science, 243(4895): 1173-1176.
[29]	Reasenberg P A, Jones L M. 1990. California aftershock hazard forecasts[J]. Science, 247(4940): 345-346. PMID
[30]	Rhoades D A. 2013. Mixture models for improved earthquake forecasting with short-to-medium time horizons[J]. Bulletin of the Seismological Society of America, 103(4): 2203-2215.
[31]	Rhoades D A, Liukis M, Christophersen A, et al. 2015. Retrospective tests of hybrid operational earthquake forecasting models for Canterbury[J]. Geophysical Journal International, 204(1): 440-456.
[32]	Shebalin P, Narteau C, Holschneider M, et al. 2011. Short-term earthquake forecasting using early aftershock statistics[J]. Bulletin of the Seismological Society of America, 101(1): 297-312.
[33]	Shebalin P, Narteau C, Zechar J D, et al. 2014. Combinning earthquake forecasts using different probability gains[J]. Earth, Planet and Space, 66:37.
[34]	Utsu T. 1961. A statistical study of on the occurrence of aftershocks[J]. The Geophysical Magazine, 30: 521-605.
[35]	Wilks D S. 2010. Sampling distributions of the Brier score and Brier skill score under serial dependence[J]. Quarterly Journal of the Royal Meteorological Society, 136(653): 2109-2118.
[36]	Woessner J, Wiemer S. 2005. Assessing the quality of earthquake catalogues: Estimating the magnitude of completeness and its uncertainty[J]. Bulletin of the Seismological Society of America, 95(2): 684-698.
[37]	Zaliapin I, Ben-Zion Y. 2013. Earthquake clusters in southern California I: Identification and stability[J]. Journal of Geophysical Research: Solid Earth, 118(6): 2847-2864.
[38]	Zhang S F, Zhang Y X, Li S. 2024. Time-dependent aftershock probabilistic forecasting and ensemble model implementation: Insights from the 2021 M_S7.4 Maduo earthquake[J]. Seismological Research Letters, 95(6): 3517-3531.
[39]	Zhuang J C, Ogata Y, Wang T. 2017. Data completeness of the Kumamoto earthquake sequence in the JMA catalog and its influence on the estimation of the ETAS parameters[J]. Earth, Planets and Space, 69(1): 36.