Earthquake catalogue

The first instrumentally recorded seismic event in the Groningen gas field was an earthquake with local magnitude 2.4 in 1991. When the event took place, the mean reservoir pressure had already decreased from the initial 350 bar to below 200 bar. With ongoing reservoir gas production the induced seismicity continued leading to the installation of a regional borehole seismic network by 1995 (Dost et al., Reference Dost, Ruigrok and Spetzler2017). In the following years, the annual number of recorded earthquakes fluctuated around ten to fifteen events per year until about 2003 when it started to increase, to nearly 120 in 2017. Figure 1(top) shows the annual number of event in different magnitude categories. The largest magnitude observed to date is the 3.6 event near Huizinge in 2012.

Fig. 1. Number of earthquakes in the Groningen field in different magnitude categories. This Figure is created by first rounding the magnitudes to 1 decimal place and subsequently assigning the earthquakes to their magnitude categories. Only events within the outline of the Groningen gas field are included (see also Fig. 2 ). Top view: all recorded events in said space/time window. Bottom view: the events above the minimum magnitude included in the current study (336 in total).

The sensitivity of the monitoring network has not been uniform in space and time. A relatively safe (conservative upper bound) estimate of the completeness level over the entire period and region is a magnitude of 1.5 (Dost et al., Reference Dost, Ruigrok and Spetzler2017). For the purpose of the current study we adopt this level as the minimum threshold ${m_{{\rm{min}}}}$ for earthquakes to be considered. In fact, since we use unrounded magnitude values we slightly relax the threshold to ${m_{{\rm{min}}}} = 1.45$ , as the value 1.5 was specified for magnitude values rounded to one decimal place. Figure 1(bottom) shows the annual number of events in the curated catalogue.

We note that the current study might, in principle, benefit from an enlarged data set by taking into account a time-dependent completeness level (Dost et al., Reference Dost, Ruigrok and Spetzler2017; Varty et al., Reference Varty, Tawn, Atkinson and Bierman2021). However, by taking a conservative assumption here, we largely steer clear of discussions on how the spatiotemporal completeness level should be estimated and to what extent imperfections would affect the results (e.g. Herrmann & Marzocchi, Reference Herrmann and Marzocchi2020). Also, since one of our objectives is to provide forecasting models for risks that occur only at magnitudes that are several units larger than the completeness magnitude (say, magnitude 4 and beyond), it is questionable whether we should go as low as we possibly can. After all, the lower we choose the range of input data for our model inference, the larger the distance we effectively have to extrapolate at a later stage.

We obtained the Groningen earthquake catalogue from the Seismological Service of the KNMI (KNMI, 2022b) through their FDSN Event Web Service (URL found in reference KNMI (2022a)), which provides origin times, locations in WSG-84 coordinates and unrounded local magnitudes. Epicentral coordinates have subsequently been transformed into the local Amersfoort/RD New coordinates system (epsg.io, 2022). The hypocenter depth is not used. We selected all earthquakes above ${m_{{\rm{min}}}} = 1.45$ , in the time window between 1 January 1995, T00:00 and 1 January 2022, T00:00. To avoid interference of earthquakes due to other exploration activities in the vicinity as much as possible, the spatial extent of the catalogue is limited to the Groningen gas field outline (NAM, 2021). The total number of events in the curated catalogue is 336. Figure 2 shows the catalogue of all earthquakes of the Groningen gas field.

Fig. 2. Map view of the Groningen gas field and its location inset (in red at the top-left corner). Locations of all recorded induced earthquakes at any time in the vicinity are shown by grey dots. The colored dots represent the earthquakes included in the current study, that is, within the field outline and the time span from 1995-01-01 to 2022-01-01, and (1 decimal rounded) magnitudes of 1.5 and higher. The colors represent the magnitude categories, analogous to Fig. 1.

Gutenberg–Richter magnitude distribution

We employ the classical Gutenberg–Richter relation (Gutenberg & Richter, Reference Gutenberg and Richter1941, Reference Gutenberg and Richter1944), as a model for the magnitude distribution of induced earthquakes in the Groningen gas field. The survival function, or probability $P[Mm|M{m_{{\rm{min}}}}]$ of a random magnitude sample $M$ exceeding $m$ , under the condition that it exceeds ${m_{{\rm{min}}}}$ is given by:

(1) $$P[M \ge m|M \ge {m_{{\rm{min}}}}{] = 10^{ - b(m - {m_{{\rm{min}}}})}},$$

with $b$ the exponential parameter, or b-value, and its probability density function as:

(2) $${f_M}(m) = - {{{\rm{d}}P[M \ge m|M \ge {m_{{\rm{min}}}}]} \over {{\rm{d}}m}}$$

(3) $$ = {b^*}{e^{ - {b^*}(m - {m_{{\rm{min}}}})}},$$

where ${b^*} = b\log (10)$ .

Unlike previous authors (Bourne & Oates, Reference Bourne and Oates2020), we do not consider a dedicated prescription of the high-magnitude tail of the distribution such as a truncation or a taper. The focus of our efforts is to find evidence for any significant spatiotemporal variation of the magnitude distribution. However, as argued in Marzocchi et al. (Reference Marzocchi, Spassiani, Stallone and Taroni2019) and Bourne and Oates (Reference Bourne and Oates2020), among others, failure to recognize and accommodate a truncated or tapered tail may lead to artifacts appearing in b-value estimates, especially if the tail starts close to the ${m_{\min }}$ considered. However, we argue that if a tail effect is relevant, in the sense that it is somehow exposed in the data, then such artifacts may actually help to reveal any spatiotemporal variation of this effect through the analysis of the b-value. We only need to keep in mind that any significant spatiotemporal variation in the assessed b-value does not necessarily have to be caused by a variation in the exponential character of the distribution, but may also be caused by variations in the tail behaviour that we do not model explicitly.

In this study we are interested in spatiotemporal variations of the b-value $b$ , so that we can express it as a function of time $t$ and space coordinates $x$ . More specifically, we test prospective predictors that may act as a spatiotemporal covariate $c(t,x)$ for the b-value:

(4) $$b = {g_C}(c(t,x),\theta ),$$

where we use a generic functional form ${g_C}$ that depends on covariate $c(t,x)$ and a, generally multivariate, parameter set $\theta $ , which represents, for example, the coefficients in functional form. We investigate a number of functional forms (i.e. models) with corresponding parameter sets, for which we infer information from the data.

The inference of model parameters starts with expressing the log-likelihood of the model, conditional on the data. The likelihood is defined as:

(5) $${\cal L}(\theta |\{ ({c_i},{m_i}),i = 1 \ldots N\} ) = \prod\limits_{i = 1}^N {f_M}({m_i}|{c_i},\theta ),$$

with ${m_i}$ the magnitude, and ${c_i} = c({t_i},{x_i})$ the covariate based on the time and location of each event $i$ out of $N$ events in the catalogue. Each event in the catalogue is associated to a specific b-value b_i:

(6) $${b_i} = {g_C}({c_i},\theta ),$$

such that the log-likelihood equals:

(7) $$\matrix{ {\log ({\cal L})(\theta |\{ ({c_i},{m_i}),i = 1 \ldots N\} ) = \sum\limits_{i = 1}^N {[\log (b_i^*)} } \hfill\cr {\quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad - b_i^*({m_i} - {m_{\min }})].} \hfill\cr} $$

Note that for a constant b-value a maximization of $\log ({\cal L})$ is achieved algebraically in closed form by the maximum likelihood estimate (MLE) b-value ${b_{{\rm{MLE}}}}$ :

(8) $${b_{{\rm{MLE}}}} = {{{{\log }_{10}}e} \over {\bar m - {m_{\min }}}}$$

where $\bar m$ is the arithmetic mean of the magnitudes in the data set (Aki, Reference Aki1965). For non-constant models the maximum-likelihood parameters can be found by maximizing the log-likelihood for model parameter vector $\theta $ to find ${\theta _{{\rm{MLE}}}}$ . This search can be done using a gradient ascent algorithm or an exhaustive grid search.

Assuming a constant b-value we have determined the MLE b-value for the entire catalogue: ${b_{{\rm{MLE}}}} = 0.96$ . The result is shown together with the empirical distribution in Fig. 3.

Fig. 3. Empirical complementary cumulative distribution function (CCDF), or probability of exceedance per event. Also shown is the maximum-likelihood Gutenberg–Richter distribution under the assumption of a constant b-value. MLE for the constant b-value is 0.96.

Static and dynamic predictors

In Bourne and Oates (Reference Bourne and Oates2020), the authors propose two models for the spatiotemporal evolution of the magnitude distribution, that are both conditioned on the induced stress (“Coulomb stress”) predictor: one with a constant b-value and a stress-dependent high-magnitude taper, and one without a taper but with a stress-dependent b-value. On the basis of physical considerations and the result of some statistical tests the authors express a preference for the former model. As mentioned in sec:intro, they did not investigate or report alternative predictors for the magnitude distribution.

Similar to the approach of Bourne and Oates (Reference Bourne and Oates2017) for activity rate prediction, we investigate a range of physical reservoir properties as predictors for the b-value throughout the Groningen gas field. These prospective predictors are related to the geological layout of the gas reservoir, the gas depletion process itself, or a combination of both.

• Reservoir thickness The reservoir thickness $h(x)$ is a 2-D spatial representation of the thickness of the Rotliegend reservoir formation, provided by the field operator (NAM, 2021) and is given in units of meters. The thickness is assumed to be static (time-invariant) and independent of the gas production. The (relatively small) compaction of the reservoir due to the gas extraction is considered as a separate prospective predictor below.

• Topographic gradient The topographic gradient Γ(x) is a spatially smoothed, 2-D, static measure of the roughness of the topography of the top of reservoir. This roughness is largely due to faults with varying offsets (Bourne & Oates, Reference Bourne and Oates2017). It is calculated based on the locations and offsets of the pre-existing faults in the reservoir, and is controlled by two parameters: ${r_{{\rm{max}}}}$ and $\sigma $ . The parameter ${r_{{\rm{max}}}}$ describes an upper cut-off value for the local fault offset-to-thickness ratio. Faults with an offset-to-thickness ratio larger than ${r_{{\rm{max}}}}$ are disregarded in the calculation. The final property is calculated by mapping the fault offsets that pass the ${r_{{\rm{max}}}}$ filter onto a regular grid, which is subsequently smoothed by a Gaussian kernel with kernel size $\sigma $ . As a result, the property is roughly proportional to both fault offset and fault density. A ready-made topographic gradient grid with parameter values ${r_{{\rm{max}}}} = 1.1$ and $\sigma = 3500$ m is supplied by the operator (NAM, 2021; Bourne & Oates, Reference Bourne and Oates2020).

• Pressure drop The pressure drop $\Delta P(t,x)$ is at any time $t$ a 2-D spatial representation of the vertically averaged pore pressure depletion in the reservoir with respect to the original (pre-production) gas pressure, provided by the operator (NAM, 2021). This property is dynamic (time-dependent) and naturally depends on the gas production.

• Reservoir compaction The reservoir compaction $\Delta h(t,x)$ is at any time $t$ a 2-D spatial representation of the change in reservoir thickness as a result of the gas pressure decline. This covariate is defined as:

(9) $$\Delta h(t,x) = \Delta P(t,x) \times {c_m}(x) \times h(x)$$

where $\Delta P(t,x)$ is the dynamic pressure drop, ${c_m}$ is the poro-elastic coupling coefficient, and $h(x)$ is the reservoir thickness. These are all provided by the operator (NAM, 2021). Reservoir compaction is a dynamic (time-dependent) property due to its dependence on the gas production.

• Induced stress The induced stress at any time $t$ is a 2-D spatial property representing the (spatially smoothed) change in Coulomb stress on pre-existing faults according to the thin-sheet model. It is calculated in accordance with Bourne and Oates (Reference Bourne and Oates2017) as ^{Footnote 1} :

(10) $$\Delta C(t,x) = {\rm{\Gamma}} (x) \times \Delta P(t,x) \times {{{c_m}(x)} \over {H_s^{ - 1} + {c_m}(x)}}$$

where Γ(x) is the topographic gradient, and ${H_s}$ is a stiffness parameter. Both Γ(x) and ${H_s}={10^7}$ MPa are supplied by the operator (NAM, 2021). Induced stress is dynamic due to its dependence on the gas production. We note that the use of a spatial Gaussian smoothing kernel in the calculation of the topographic gradient makes it difficult to interpret the numerical values of this covariate field in terms of absolute stress changes. Rather, it is a metric that combines fault density of faults below a certain offset-to-thickness ratio and vertical compaction strain. In a stricter sense, it is perhaps best interpreted as a propensity-to-failure proxy, rather than Coulomb stress change.

Along with the above five prospective predictors representing physical properties of the reservoir, we also take time as a possible predictor to complete a set of six predictors that we submit to the same sequence of statistical tests. Figure 4 illustrates the spatial variation patterns of the six predictors. The figures come without explicit legend, serving as a visual representation of the spatial patterns. For the dynamic predictors (pressure drop, reservoir compaction and induced stress), the situation at the end of the observation period (i.e. 2022-01-01) has been chosen. The numerical value ranges of the predictors are shown in Table 1.

Fig. 4. The six predictors for b-value variations investigated in this study represented as contour plots within the outline of the Groningen field. Each figure is individually scaled, where green colors correspond to the lowest, orange to the highest values. Representative values for the covariates are presented in Table 1 . For the dynamic predictors (pressure drop, reservoir compaction and induced stress), the state at the end of the observation period (i.e. 2022-01-01) is shown.

Table 1. Predictor value ranges as sampled by the catalogue.

In the statistical analysis that follows, earthquakes are associated, or ’labelled’, with the predictor values at the origin time and location of the earthquake according to the catalogue. For example, for the predictor reservoir thickness, we label each earthquake with the reservoir thickness at the location of the earthquake, while for the predictor induced stress, we label each earthquake with the induced stress at the location and the origin time of the earthquake. To facilitate the statistical analysis, after the earthquakes have been labelled, we perform a linear rescaling to the covariate values, such that the earthquake with the lowest covariate value receives a covariate value of 0 and the earthquake with the largest covariate value receives rescaled value of 1. In most figures, the minimum and maximum covariate values are simply labeled as ‘min’ and ‘max’ respectively.

The labelling of each event by the predictor values determines an ordering of observed magnitudes specific to that predictor. These predictor-specific orderings are displayed in Fig. 5. The corresponding value ranges are given in Table 1. If a reservoir property has a predictive capacity with regard to the magnitude distribution, then the ordering (and spacing) of the magnitudes may be distinguishable from random orderings. In that case, the property has the potential to be used as a predictor in a seismic hazard and risk forecasting. In the following section we use this concept of ordering to define a null hypothesis.

Fig. 5. For each of the six prospective predictors, the magnitudes of the earthquakes in the seismic catalogue are plotted against the predictor value. Each predictor provides it own specific ordering and spacing of the catalogue.

Statistical toolkit

Cramér-von Mises test

The maximum-likelihood regression of the step model effectively leads to a partitioning (in two parts) of both the predictor range and the catalogue ordered according to this predictor, each with a constant b-value. The significance of this partition can be further studied by a two-sample goodness-of-fit test. Such a test attempts to reject the null hypothesis that the two samples are actually generated by the same distribution. Commonly applied tests include Kolmogorov-Smirnov, Anderson-Darling, and Cramér-von Mises (Stephens, Reference Stephens1970; Darling, Reference Darling1957). For our experiments we picked the Cramér-von Mises test as it turned out to be the most efficient in terms of computation time, while there was no particular reason to prefer one over the other.

Important to note, however, is that the p-value result from the goodness-of-fit test cannot be used without the following consideration. Due to the maximum-likelihood optimization of the step model, the two subsets are not completely independent anymore. In fact, the total likelihood of the step model benefits if both subsets are as dissimilar as possible. As a result, an overabundance of low p-values is to be expected even for the null hypothesis. Therefore, the Cramér-von Mises test needs to be recalibrated for this particular purpose. This is achieved by the experiment illustrated in Fig. 6. The yellow curve shows that the Cramér-von Mises test works as expected for random partitions of a Groningen-sized constant b-value catalogue. The blue curve shows that introducing the optimization step compromises the test results. However, a correction is obtained relatively easily by applying the inverse CDF of the p-value distribution (blue curve). The formal test result appears on the horizontal axis, while the corrected result appears on the vertical axis. A formal Cramèr-von Mises p-value of 0.05 should be corrected to a p-value of 0.36 for this experiment (as indicated by the grey crosshair).

Fig. 6. Results of applying the Cramér-von Mises test on two subsets of 10,000 randomly drawn catalogues (N = 336, b = 0.96). For each catalogue, a random split point is chosen in the catalogue, and an optimal split point is found by considering the step location of the maximum-likelihood step function. The Cramér-von Mises test is then applied, and a p-value is obtained for subsets created by the random split point and the optimal split point. The blue curve shows a CDF of p-values obtained over 10,000 catalogues for the optimal split point, while the yellow curve shows the CDF for the random split points. The Cramér-von Mises p-values for the yellow curve are distributed homogeneously between 0 and 1, while the blue curve shows an overabundance of low p-values. This indicates that the likelihood optimization corrupts the test, which should be corrected for. In fact, the blue curve provides the correction: the formal test result appears on the x-axis, while the corrected test result appears on the y-axis.

Likelihood ratio and the Akaike information criterion

As we investigate a total of six prospective predictors and five functional forms, we have quite a collection of statistical models for which we can assess the performance in terms of their maximum-likelihood with respect to the Groningen observations. At this point we immediately want to make the disclaimer that we do not intend to apply these maximum-likelihood models directly to hazard and risk assessments. For that purpose we prefer to apply the models in a Bayesian context, where we can take all uncertainties into account and make use of probability distributions of the model parameters rather than just the maximum-likelihood point estimates used in this study. Moreover, we would like to submit these models to pseudo-prospective testing and performance assessment before deciding on their use (e.g. Zechar et al., Reference Zechar, Gerstenberger and Rhoades2010; Bourne et al., Reference Bourne, Oates, van Elk and Doornhof2014).

That being said, model selection is commonly based on the likelihood-ratio test and information-theoretical extension such as the Akaike Information Criterion (e.g. Burnham et al., Reference Burnham, Anderson and Huyvaert2011; Lewis et al., Reference Lewis, Butler and Gilbert2011). These methods simply take maximum-likelihood results as an input.

The Akaike Information Criterion $AI{C_j}$ for model $j$ is defined as:

(11) $$AI{C_j} = - 2\log {{\cal L}_j} + 2{p_i},$$

where ${p_i}$ is the number of model parameters (or degrees of freedom therein). According to this definition, a lower AIC corresponds to a better performance. Two models that differ by $\Delta p$ degrees of freedom are considered to have an equal performance if their likelihoods differ by a factor ${e^{ - \Delta p}}$ . The inclusion of ${p_i}$ in Equation 11 is basically a bias correction that compensates for the higher likelihood values expected for models with a higher number of parameters under the null hypothesis that these parameters are not required.

The Akaike likelihood ratio ${{\cal R}_{ij}}$ between models $i$ and $j$ is basically a bias corrected likelihood ratio:

(12) $${R_{ij}} = \exp (AI{C_i} - AI{C_j})/2 = {e^{({p_i} - {p_j})}}{{{L_j}} \over {{L_i}}}.$$

We compute AIC-corrected likelihood ratio’s with respect to the constant b-value null hypothesis. This gives us relative measures of the model performance in terms of the relative likelihood. From an information-theory perspective these numbers indicate the relative probability that model $j$ (relative to model i) is able to minimize the information loss inherent to the abstraction of reality in terms of a (mathematical) model.

We like to note that during the evaluation of the results of our analysis we found out that the Akaike formula (11) does adequately compensate the expected likelihood gain for the step model, as illustrated in Fig. 7. Although the constant model is a nested model, that is, special case of the step model, the likelihood ratio statistics are not chi-square distributed. It turns out that relative to the null hypothesis, the step model has an advantage that is higher than the number of its free parameters (3) would suggest. As a result, the AIC likelihood ratio’s for the step model relative to the other models are expected to be inflated, that is, biased by over-fitting. The performance results of the step models should therefore be interpreted with restraint. We speculate that the cause is related to the discontinuity of the model, and to the fact that the null hypothesis does not constrain the third parameter, that is, the location of the discontinuity. Exploration of this specific hypothesis is beyond the scope of this paper. We expect that in a pseudo-prospective model performance testing procedure (Zechar et al., Reference Zechar, Gerstenberger and Rhoades2010), that we anticipate any new model to be subjected to before application in hazard and risk assessment, this issue will be treated adequately.

Fig. 7. Likelihood ratio statistics for maximum-likelihood linear, quadratic and step b-value functions, relative to the maximum-likelihood constant b-value model. The statistics are obtained for 1000 random reassignments of the magnitudes to the catalogue’s reservoir thickness samples. Other predictors give comparable results. Both the linear and quadratic functions closely follow a maximum-likelihood chi-square distribution (dashed curves), with degrees of freedom very close to the theoretic values of 1 and 2, for functions with 1 and 2 degrees of freedom more, respectively, than the constant function. The step function, however, also has just two more parameters than the constant function, but apparently is expected to perform much better than the quadratic, and apparently is not chi-square distributed (the dashed curve is the maximum-likelihood chi-square fit to the data). As a result, the Akaike Information Criterion does not compensate adequately for the surplus degrees of freedom.