Clustering features and seismogenesis of the 2014 M6.6 Jinggu earthquake in Yunnan Province, China

Zheng, Jianchang

doi:10.3389/feart.2023.1177821

ORIGINAL RESEARCH article

Front. Earth Sci., 19 June 2023

Sec. Solid Earth Geophysics

Volume 11 - 2023 | https://doi.org/10.3389/feart.2023.1177821

This article is part of the Research Topic Pre-, Co-, and Post-Seismic Processes of Recent Earthquakes in Mainland China View all 9 articles

Clustering features and seismogenesis of the 2014 M6.6 Jinggu earthquake in Yunnan Province, China

Jianchang Zheng*

Shandong Earthquake Agency, Jinan, China

Seismic activities can be seen as the composition of background and clustering earthquakes. It is important to identify seismicity clusters from background events. Based on the Nearest Neighbour Distance algorithm proposed by Zaliapin, we use the Gaussian mixture model (GMM) to fit its spatiotemporal distribution and use the probability corresponding to clustering seismicity in the GMM model as the clustering ratio. After testing with synthetic catalogues under the ETAS (epidemic-type aftershock sequence) model, We believe the method can discriminate cluster events from randomly occurring background seismicity in a more physical background. We investigate the seismicity and its clustering features before the M6.6 Jinggu earthquake in Yunnan Province, China on 7 October 2014. Our results show the following: 1) The seismogenic process of this strong earthquake has three stages, which are already described by the IPE model (the model is similiar to dilatancy diffusion model, growth of cracks is also involved but diffusion of water in and out of the focal region is not required); 2) The main shock might have been caused by the breaking of a local locked barrier in the hypocentre, and the meta-instability stage was sustained for about 1 year on the fault. From this study, we conclude that the evolution of seismicity clustering features can reflect changes in stress in the crust, and it is closely connected to the seismogenic process of a strong earthquake.

1 Introduction

Seismic data can be regarded as a combination of background and clustering earthquakes (Zhuang et al., 2005). These two parts have different tectonic genesis and physical mechanisms (Zhuang et al., 2005; Jagla and Kolton, 2010; Hardebeck, 2021): Background earthquakes are assumed to be mostly caused by secular, tectonic loading or, in the case of seismic swarms, by stress transients that are not caused by previous earthquakes; Clustering earthquakes triggered by static or dynamic stress changes, seismically-activated fluid flows, after-slip, etc., hence by mechanical processes that are at least partly controlled by previous earthquakes (van Stiphout et al., 2012). The identification and statistical characterisation of seismic clusters may provide useful insights about the features of seismic energy release and their relation to physical properties of faults (Peresan and Gentili, 2018). The identification of clustering earthquakes is important for many applications in seismology, including seismic hazard assessment, earthquake prediction research, and seismicity rate change estimation (Bayliss et al., 2019). Since clustering earthquakes are mainly affected by earthquakes that have already occurred, the so-called “parent event”, and their physical properties and mechanisms are different from background seismicity, therefore, it is often necessary to separate the two groups of events (Zhang and Shearer, 2016).

Studies have shown that seismicity clusters can occur before moderate and strong earthquakes (Yamashita and Knopoff, 1992; Evison and Rhoades, 1999; Ma et al., 2013). Dieterich (1994) believed that small earthquake clustering is driven by changes in stress near the seismic zone and may be related to the nucleation process of large earthquakes. This has been confirmed by rock tests (Yang et al., 1998). Background seismicity also changes regularly during stress changes caused by a strong earthquake (Ellsworth et al., 1981); therefore, by using relative ratio changes between cluster and background events, we can estimate the risk of a future strong earthquake (Cao et al., 1996).

Many methods exist to quantify the spatiotemporal clustering of earthquakes, as well as to distinguish background and clustering events in seismic activity (e.g., Gardner and Knopoff, 1974; Reasenberg, 1985; Reasenberg and Jones, 1989; Molchan and Dmitrieva, 1992). Pioneering methods include the earthquake concentration C-value as defined by Wang (1984), which is a function based on frequency per unit area; and the seismic spatial clustering (Js) and temporal clustering degree (Jt) based on the Morishita index of Zhang and Jiang (1996). Later studies include the commonly used windowing methods (Gardner and Knopoff, 1974; Reasenberg, 1985) and a stochastic declustering method based on the ETAS model (Zhuang et al., 2002).

Pei et al. (2004) assumed that background and clustering earthquakes satisfy the 2D Poisson process with different parameters. By introducing the concept of N-order distance, a superimposed 2D Poisson process is transformed into a 1D mixed-density function. Based on the selected distance order, a genetic algorithm can be used to decompose the mixed density and then analyse the seismic clustering mode (Zaliapin et al., 2008; Zaliapin et al., 2011). considered factors such as the spatiotemporal distribution and energy of earthquakes and defined the nearest neighbour distance (NND) between different events, from which a method for analysing clustering earthquakes and identifying aftershocks was derived. Promising results have been obtained from applications of this method in recent years (Zaliapin and Ben-Zion, 2013a; Zaliapin and Ben-Zion, 2013b; Zaliapin and Ben-Zion, 2016a; Zaliapin and Ben-Zion, 2016b).

Building on previous work (Zheng et al., 2014; Wang et al., 2017), we develop Zaliapin’s method using a Gaussian mixture model (GMM). Using the M6.6 Jinggu earthquake in Yunnan Province on 7 October 2014 (hereinafter “Jinggu earthquake”) as an example, we analyse the spatiotemporal clustering characteristics of regional small earthquakes before a strong earthquake.

2 Theory and method

2.1 NND algorithm

For a given earthquake catalogue $\{t_{i}, θ_{i}, φ_{i}, h_{i}, m_{i}\}, i = 1 \dots N$ , $t$ is the earthquake occurrence time, $θ, φ$ is the longitude and latitude of the epicentre, respectively, $h$ is the hypocentral depth, and $m$ is the magnitude. Not considering the depth, the time-space-magnitude distance between any two seismic events is defined as (Zaliapin et al., 2008):

n_{i j} = \{\begin{array}{l} c τ_{i j} r_{i j}^{d} 10^{- b (m_{i} - m_{0})} \\ \infty \end{array} \begin{array}{l} τ_{i j} \geq 0 \\ τ_{i j} < 0 \end{array} (1)

where $τ_{i j} = t_{j} - t_{i}$ , $r_{i j}$ is the surface distance, $m_{0}$ is the reference magnitude, $c$ is the constant coefficient, $d$ is the fractal dimension of earthquake epicentres, and $b$ is the $b$ -value of the Gutenberg-Richter relation.

In a given time-space magnitude, the nearest neighbour is defined as follows:

η_{j}^{*} = \min_{i} n_{i j} (2)

Zaliapin et al. (2008) proved through theoretical analysis that if the assumption is that the earthquake process is a stable stochastic Poisson process with a certain probability density, and the magnitude marks $m_{i}$ are independent of the time-space random variables ( $t_{j}, θ_{j}, φ_{j}$ ) and have exponential distribution, then the NND satisfies the Weibull distribution and is independent of the lower magnitude threshold $m_{0}$ .

It is possible to further define the temporal and spatial components of the magnitude-normalised NND:

T_{i j} = τ_{i j} 10^{- b m_{i} / 2}, R_{i j} = r_{i j}^{d} 10^{- b m_{i} / 2} (3)

$η = T R$ (without loss of generality, it is assumed here $c = 1, m_{0} = 0$ ).

In the previous statistical methods for analysing seismic activity, time, space and energy domains were often separated and not considered together. The NND defined by Zaliapin et al. (2008) comprehensively considers the distribution of earthquakes in the space, time and energy domains and provides normalised parameters, which effectively simplifies the complex problem of the N-dimension.

2.2 The ETAS model

The ETAS model is a self-exciting point process (Ogata, 1999) that describes the spatiotemporal clustering of seismicity, which accounts for secondary aftershock excitation with statistically self-similar features and has notable significance in terms of statistical physics. Therefore, it is widely used to study the spatiotemporal features of regional seismicity as well as features of aftershock activity (such as Jiang et al., 2007; Jiang and Zhuang, 2010).

Assuming that each earthquake triggers its aftershocks and aftershock activity follows the Omori-Utsu formula in the time domain, in the ETAS model, the frequency of aftershocks per unit time t is as follows:

n_{j} (t) = K \exp {[α (m_{j} - m_{0})] / (t - t_{j} + c)}^{p} (4)

where $m_{0}$ is the lower magnitude threshold, $M_{i}$ and $t_{i}$ are the magnitude and origin time of the i-th earthquake. $K$ , $α$ , $c$ , and $p$ are constants, which hold true for all aftershock sequences in a given area. The earthquake occurrence rate at time t is as follows:

λ (t) = μ \sum_{i} n_{i} (t) (5)

There are two parts on the right side of Eq. 5. The first is the background earthquake occurrence rate, which represents seismicity caused by external triggers, such as structural loading or increased pore pressure. The second is the aftershock sequence, which follows the modified Omori formula.

Consider point-process models for the data of occurrence times and locations of earthquakes, Ogata & Zhuang (2006) extended the ETAS model to spatiotemporal domain. The occurrence rate λ(t, x, y) of a space–time point process is mathematically defined in terms of the occurrence probability of an event at time t and the location (x, y) conditional on the past history of the occurrences. In the typical space–time extensions of the ETAS model, formula (5) can be modified as

λ (t, x, y) = μ (x, y) + \sum_{\{j : t_{j} < t\}} n (t - t_{j}) \times g (x - x_{j}, y - y_{j}, m_{j} - m_{0}) (6)

2.3 A Gaussian mixture model of background and clustering earthquakes

Earthquakes can be regarded as a spatiotemporal stochastic point process (Ogata, 1988; Console et al., 2003; Holden et al., 2003); in particular cluster earthquakes can be regarded as a self-exciting spatiotemporal stochastic point process (Reinhart, 2018). Assuming that background earthquakes and clustering earthquakes are generated by different stochastic processes, and taking into account the spatiotemporal distribution of NND $η^{*}$ in each process, GMM can be used for analysis. A single spatiotemporal stochastic process satisfies a 2D normal distribution. For seismic activity within a certain spatiotemporal range, a GMM of K=2 can be selected. There are two Gaussian models in GMM, one for background earthquakes, and the other for clustering earthquakes. The probability density function (PDF) of GMM is as follows:

f (η) = w_{1} * f_{1} (η) + w_{2} * f_{2} (η) (7)

where f₁(η), f₂(η) are two Gaussian PDFs for seperately modeling background and clustering earthquakes. The coefficient w_k is the weight of the k-th Gaussian model for $k = 1,2$ , which is known as the probability of selecting the k-th model and satisfies $Σ_{k = 1}^{K} w_{k} = 1$ .

2.4 Numerical test

Figure 1A shows the M-t diagrams of 1,000 simulated earthquakes generated by the ETAS model. The catalogue was generated using the code from Helmstetter and Sornette (2002). The initial parameters of the ETAS model were: $b$ = 1.000, $p$ = 1.200, $α$ = 0.800, $K$ = 0.018, and $c$ = 0.010; another parameters of spatial window were: R = 50 km, Z_max = 20 km, R is radius and Z is depth. A histogram of NND $η^{*}$ and the 2D distribution of the space-time components of $η^{*}$ are shown in Figures 1B, C. Following the method of Pei et al. (2004), seismic activity is considered to be two superimposed normal distributions, so mixed density decomposition was performed on the statistical results shown in Figure 1D Finally, two weighted probability density functions (PDFs) of normal distribution were obtained. The one on the left can be regarded as the probability distribution of the background event, and the other can be regarded as the probability distribution of clustering earthquakes (Figure 1E).

FIGURE 1

FIGURE 1. (A) Temporal distribution of M>=1.0 events in synthetic catalogues; (B) Spatiotemporal distribution of η*; (C) Contour map of distribution density of panel (B); (D) Histogram of η*; (E) Fitted mixture PDF (red).

Based on the GMM, we analysed the earthquake catalogue simulated by the ETAS model. The GMM was used to solve the 2D distribution of the NND $η^{*}$ in Figure 1B (for results, see Figure 2). Evidently, the GMM fits the spatiotemporal distribution of $η^{*}$ and distinguishes background earthquakes from clustering earthquakes in the statistical physics sense. The calculated relative weights were w₁ = 0.582 and w₂ = 0.418. In other words, within the given space-time scope of the simulated catalogue, if an earthquake event occurred, the probability of it being a background event caused by tectonic activity was 58.2%, and the probability of it being a clustering event influenced by an earthquake that had already occurred was 41.8%. We used the probability corresponding to clustering seismicity as the clustering ratio within this spatiotemporal range.

FIGURE 2

FIGURE 2. Contour map of PDFs of the GMM model for earthquakes shown in Figure 1.

3 Data and study area

The M6.6 Jinggu earthquake took place on 7 October 2014 in the Lanping-Simao Basin on the west side of the Honghe fault zone in southern Yunnan (Xu et al., 2014; Chang et al., 2016; Mao et al., 2019). It was the only M ≥ 6.5 earthquake to occur in southern Yunnan in the past decade. It was a highly significant seismic event, but there has been little relevant research on the earthquake (geophysical research includes Li et al., 2015; Sun et al., 2015; Zhang et al., 2018), with particularly few studies on pre-earthquake seismicity (only Luo et al., 2016; He et al., 2019).

Based on the method of analysing clustering earthquakes proposed above, we analysed the clustering characteristics of regional seismic activity before moderate and strong earthquakes using the Jinggu earthquake as an example. Referring to the numerical simulations by Zhou et al. (1994) and theoretical analysis by (Mei et al., 1995; Mei et al., 1996) on deformation field, Zhang and Jiang (1996) think the statistical area should be 200–300 km while study on seismic activities prior to a strong earthquake. So we used the Jinggu earthquake epicentre as the centre point with a radius R = 150 km and studied the seismic records between 1 January 2009 and 30 September 2014 (Figure 3).

FIGURE 3

FIGURE 3. Distribution of M_L ≥ 1.0 events (black dots) and faults (red lines) in south Yunnan, star denotes the Jinggu M6.6 earthquake, the faults name are given on Figure 7; right panel shows the Gutenberg-Richter relationship of seismicity in the study area, pink line represents fitted result.

In the application of this paper, first, according to the Gutenberg-Richter relation of the earthquake catalogue in the study area, the minimum magnitude of completeness M_c = M_L 1.5 of the area was determined (Figure 3B), and the $b$ -values of the selected area were determined using the least squares method. Then, MapSiS was used to obtain the spatial fractal dimensions $d$ of the distribution of earthquakes and calculate the NND $η^{*}$ for each event. Finally, GMM was calculated for the 2D distribution of the space-time components (T, R) of $η^{*}$ ; Here, an EM (Expectation Maximization) algorithm is adopted to estimate the parameters of GMM model. The results were then analysed.

4 Computation and analysis

With the Jinggu earthquake as the centre, we selected M_L ≥ 1.5 earthquakes within a radius of 150 km between 1 January 2009 and 30 September 2014 and used the GMM approach above to calculate the earthquake clustering ratio in the area (Figure 4). The NND $η^{*}$ statistical results (Figure 4B) show that the area is dominated by background seismic activity, but with a certain proportion of clustering earthquakes. It can also be seen from the spatiotemporal distribution of $η^{*}$ that background events are concentrated in an ellipse around the straight line $\log_{10} T + \log_{10} R = 0.719$ (Figures 4A, C), with some relatively dense clusters in the lower left of the diagram. According to a previous analysis, these correspond to clustering earthquakes. We used the GMM to match the spatiotemporal distribution shown in Figure 4A (see Figure 4D). It can be seen that two Gaussian distributions can be used for a good fit of the spatiotemporal distribution of $η^{*}$ . The probabilities of the two types of earthquakes were calculated as w₁ = 0.568 and w₂ = 0.432. We define the latter as the clustering ratio of seismic activities within a spatiotemporal range.

FIGURE 4

FIGURE 4. Results of nearest neighbour algorithm of M_L ≥ 1.5 seismic activities around 2014 Jinggu M6.6 earthquake (within a radius of 150 km). (A) Distribution of spatial and temporal components of η*, (B) histogram and its fitted PDF of η*; (C) Density contour map ofη*; and (D) PDFs of fitted GMM model.

4.1 Temporal variation of small earthquake clusters

The seismic clustering ratio was calculated for each natural year (window size: 365 days, and step size 30 days) of the earthquake catalogue within a 150 km radius around the Jinggu earthquake (Figure 5). According to the definition of $η^{*}$ , the b-value of the Gutenberg-Richter relation and the fractal dimension d of the epicentre distribution are required to calculate $η^{*}$ . As both are related to the stress and the non-uniform nature of the fault plane (Wyss et al., 2004), Figure 5 also shows changes in these two intermediate parameters over time.

FIGURE 5

FIGURE 5. Plots of magnitude (D), fractal dimension (A), b-value (B), and clustering ratio (C) versus time. The blue horizontal dashed lines represent standard deviation, and green lines are mean values.

Figure 5 shows that the evolution of small earthquake activity parameters before the Jinggu earthquake can be divided into three clear stages. Stage I: In 2010–2011, the fractal dimension d of the epicentre showed declined and then recovered, while the b-value increased and clustering remained below the mean level; the decrease in the fractal dimension indicated a strengthening of the orderly spatial distribution of seismic activity, but the simultaneous increase in b-value meant that the regional mean stress was still low (Wyss et al., 2004). Stage II: From October 2011 to September 2013, the fractal dimension d recovered somewhat, while the b-value was very low and continued to decline; from the beginning of 2013, the b-value dropped to a level lower than the background value of 0.809, which signalled an increase in crustal stress in the study area; the degree of earthquake clustering in the study area increased significantly at this point as the b-value decreased. Stage III: After October 2013 and until the mainshock, the fractal dimension d did not change significantly, the b-value increased and returned to its mean level, and the clustering of small earthquakes declined to around the mean value with some fluctuations.

4.2 Physical interpretation of small earthquake cluster variation

Chinese and international scholars have proposed various models of the seismogenic process of strong earthquakes, such as the barrier model, dilatancy-diffusion model (DD model), Institute of Physics of the Earth model (IPE model), and integrated model (Liu and Cao, 2003). Soviet seismologist Mjachkin (Mjachkin et al., 1975) proposed the IPE model based on fracture mechanics and rock tests and divided the seismogenic process of strong earthquakes into three stages, as shown in Figure 6A. Combining the analysis of small earthquake activity before the Jinggu earthquake in Section 4.1 and the changes in Benioff strain energy in Figure 6B, we found that it conforms closely with the IPE model. From 2010 to the first half of 2011, the epicentral area had a random distribution of small ruptures as well as low regional stress (a high b-value) and strain release rate, with activity largely due to background events caused by tectonic stress, so the clustering ratio remained below 0.3 (Figure 5). In the later part of this stage, the fractal dimension d decreased, indicating that microfractures develop in an orderly direction. In the second half of 2011, the acceleration stage may have been reached, with a sharp increase in microfractures, an increase in stress (lower b-value), an acceleration in strain release, and a rapid increase in the clustering of small earthquakes to above 0.4. From the end of 2013 onwards, Stage III was reached, in which the growth of new microfractures stopped and the number of active fissures decreased. Therefore, although the fractal dimension d changed little, the clustering of small earthquakes decreased significantly until the mainshock of M6.6 occurred.

FIGURE 6

FIGURE 6. (A) Change of average deformation velocity during the seismic cycle; (B) Cumulative Benioff strain energy (relative energy, take M_L0.0 as 1) versus time.

4.3 Spatial variation and physical interpretation

Using the method above, spatial scanning was conducted of seismic activity in the study area (Figure 3) in the 18 months before the Jinggu earthquake. A variable window length was applied to ensure sufficient earthquakes for each scanning window. The minimum window length radius l was 10 km. If the number of earthquakes in the scanning window at a certain location was less than 100, the scanning radius was expanded at a step of 5 km until the number of earthquakes was sufficient to satisfy the requirements, with a maximum l of 50 km. The results are shown in Figure 7.

FIGURE 7

FIGURE 7. Spatial variation of clustering ratio in southern Yunnan Province. F1 Nanting River Fault; F2 Lancang River Fault; F3 Wuliang Mountain Fault; F4 Babian River Fault; F5 Amo River Fault; F6 Ailao Mountain Fault; F7 Hong River Fault; F8 Shiping-Jianshui Fault; F9 Mujia-Qianmai Fault; F10 Lancang-Mengzhe Fault; F11 Menglian Fault; F12 Daluo Fault. [The names of the faults are from Chang et al. (2016), and the star represents the epicentre of the M6.6 mainshock].

Figure 7 shows a high degree of clustering of small earthquakes concentrated around the epicentre of the Jinggu earthquake. This is particularly notable at the Lancang River Fault (F2) and the west branch of the Wuliang Mountain Fault (F3-4), which were close to the mainshock. It is even more noteworthy that the epicentral area of the Jinggu earthquake was unusually calm despite the concentration of small earthquakes in its surrounding areas, which accords precisely with the barrier model proposed by Mei et al. (1995). Geological analysis has revealed that the Jinggu earthquake occurred on an unknown secondary active fault outside the boundary fault zone (Xu et al., 2014), which may indicate that the fracture intensity at the epicentre was higher than that of the surrounding main fault.

5 Discussion and conclusion

The minimum space-time distance $η^{*}$ proposed by Zaliapin et al. can effectively distinguish background earthquakes from clustering earthquakes from a statistical physics perspective. The author used a statistical mixed model of two 2D Gaussian distributions to fit the 2D distribution of the spatiotemporal components (T, R) of $η^{*}$ . We used the probability corresponding to clustering seismicity in the GMM model as the clustering ratio within the spatiotemporal range.

Based on this method, we studied regional small earthquake activity before the Jinggu earthquake in Yunnan Province, China on 7 October 2014 and discovered the following:

1. The seismogenic process of the Jinggu M6.6 earthquake can be divided into three stages. Based on the stochastic activity of the background earthquake, stress gradually increased, small earthquakes were highly clustered, and the release of strain energy accelerated markedly 3 years before the earthquake. One year before the mainshock, the existence of a fault barrier or hypocentre barrier causes calmer rupture activity near faults. Following the accumulation of strain energy, the main shock finally occurred. The seismogenic process of the Jinggu earthquake accords with the theoretical model.

2. There was a high degree of clustering of small earthquakes concentrated around faults near the Jinggu earthquake prior to the earthquake, while the epicentral area was relatively calm, which may indicate that the epicentral area was a barrier with relatively high fracture strength and that was locally locked. It was the fracture of this barrier that caused the M6.6 Jinggu earthquake to occur.

Rock tests have shown that large fractures are preceded by increased and concentrated microfractures (Stanchits et al., 2006; Aben et al., 2019). The latest theoretical model of progressive localization of deformation before large earthquakes (Kato and Ben-Zion, 2021) states that before such an event, regional weakening will gradually form localized deformation around the eventual rupture zones, and regions containing faults of various scales experience substantial clusters of seismicity during localized deformation. Analysis of the Jinggu earthquake in this paper revealed the spatiotemporal evolution of clustering earthquakes can indeed reflect changes in tectonic stress, which is connected to the seismogenic process of strong earthquakes. Furthermore, approximately 1 year before the Jinggu earthquake, the b-value of the seismogenic area recovered and clustering decreased significantly, which was similar to the conditions before the slip instability in rock tests. Does this decrease in clustering of small earthquakes, the recovery of the b-value, and reduction in the release of strain energy after an acceleration indicate that the hypocentre has entered the sub-instability stage? This could be the focus of future studies.

Data availability statement

The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding author.

Author contributions

JZ conceived the study.

Funding

Jointly funded by the China Earthquake Science Experimental Site Earthquake Predictability International Cooperation Project (2018YFE0109700), the Earthquake Tracking and Orientation Tasks of the China Earthquake Administration, and the Science and Technology Innovation Team of the Shandong Earthquake Agency.

Acknowledgments

The catalogue used in this paper is from the unified cataloguing system of the China Earthquake Network Center. b-values and fractal dimensions were calculated using MapSiS v2.8.11 developed by Li Shengle et al. The implementation and programming of the nearest neighbour distance algorithm was based on Matlab. Thanks to the reviewers for their comments and suggestions.

Conflict of interest

The author declares that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

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