SHA#1 (CWG, June 2015)

The seismic hazard assessment followed a physics-based approach, where stress changes associated with subsurface activities were numerically simulated as described in more detail below. Subsequently, a scenario technique was applied to study the seismicity response to simulated stress changes assuming two different scenarios of subsurface conditions. These scenarios reflect the uncertainty of subsurface conditions. An ‘expected scenario’ is defined based on the geothermal project developer’s interpretation of subsurface conditions. The second ‘extreme scenario’ considers unfavourable subsurface conditions, where the Tegelen fault behaves seismogenic and is close to stress criticality at reservoir depth.

Quantifying the likelihood for the two individual scenarios was considered impossible. Instead, risk mitigation measures in terms of a traffic light protocol were defined such that damage-relevant seismicity should be avoided even in the ‘extreme scenario’. This strategy differs fundamentally from the concept of a probabilistic seismic hazard assessment (Cornell, Reference Cornell1968; McGuire, Reference McGuire1995), where risk and uncertainties are estimated quantitatively. Given the lack of previous (induced) seismicity at Californië and accounting for the non-stationary nature of induced seismicity, a probabilistic quantification of seismic hazard was considered not feasible.

The workflow of the seismic hazard assessment can be summarised as follows:

In a first step, the geological-tectonical situation at the project site was investigated (Figs. 1 and 2). Using a local interpretation of fault trajectories determined from 2-D seismic lines and the regional stress field model of Hinzen (Reference Hinzen2003), slip tendencies ST, defined as the ratio of shear to effective normal stress (Moeck et al., Reference Moeck, Kwiatek and Zimmermann2009), were calculated on all patches of the mapped faults. The resulting slip tendencies fall in the range from 0.9 to 1.1. Slip tendencies are higher than typical values of the coefficient of friction, indicating that the mapped faults in the subsurface are likely to be critically stressed. For example, for the reservoir rocks we assumed a coefficient of friction of μ = 0.6, which is in the typical range for limestones (Beblo et al., Reference Beblo, Berktold, Bleil, Gebrande, Grauert, Haack, Haak, Kern, Miller, Petersen, Pohl, Rummel and Schopper1982, table 11).

For the ‘expected scenario’, a geometrically simple reservoir model was implemented as a numerical 3-D Finite Element model in Comsol Multiphysics for simulating hydraulic pressure changes associated with (the planned) geothermal production. A Darcy flow regime (Bear, Reference Bear1975) was assumed. Poro-elastic stress changes were considered to be of secondary order and were thus discarded. Mechanical stress changes associated with thermal contraction were simulated separately using the semi-analytical solutions by Okada (Reference Okada1992) following the approach described in Baisch et al. (Reference Baisch, Carbon, Dannwolf, Delacou, Devaux, Dunand, Jung, Koller, Martin, Sartori, Secanell and Vörös2009) and parameters as listed in Tables 1 and 2. This approach approximates thermo-elastic stresses on faults located in the far field, that is beyond the cooled zone around the injection well. We have compared modelling results from the semi-analytical approach to those of a thermo-hydraulic-mechanically coupled finite element model and found a first-order consistency (see appendix).

Table 1. Parameter for the hydraulic model used in the two SHA updates. The model includes results from drilling and testing the CLG wells, resulting in a more detailed resolution of the subsurface with modified hydraulic parameter (layers of the Zeeland group are labelled L₂-L₅). Layers are thinning out in the eastern direction, and the two values denote the respective maximum / minimum thickness.

Table 2. Parameter for the computation of thermal stresses.

Numerical simulations indicate that after 5 years of production, temperature changes >0.5°C are limited to distances <325 m around the injection well and do not reach the Tegelen fault. Thermo-elastic stresses, however, can still be relevant for the seismicity evolution of the Tegelen fault (e.g. Jeanne et al., Reference Jeanne, Rutqvist and Dobson2017).

Stress perturbations on faults are described by Coulomb stress changes ΔCS (Scholz, Reference Scholz2002):

(1) $${\rm{\Delta }}CS = {\rm{\Delta }}\tau - \mu \cdot \left( {{\rm{\Delta }}{\sigma _n} - {\rm{\Delta }}{p_{fl}}} \right)$$

with $\delta \tau$ , $\delta \sigma _{n}$ and $\delta p_{fl}$ denoting changes of shear stresses, normal stresses and fluid pressure, respectively. μ denotes the coefficient of friction. Positive values of ΔCS shift the state of stress on a fault (patch) closer to failure. Coulomb stress changes along the Tegelen fault resulting from thermal contraction after 2 years of circulation at 250 m³/hrs are shown in Fig. 4. For this simulation, a pure normal faulting regime was assumed. The stress regime, however, is not well constrained, and a strike-slip regime was considered equally likely in the seismic hazard assessment. At a later stage, we will show that a similar pattern of Coulomb stress changes rotated by 90° results when assuming a strike-slip regime (Fig 10).

Fig. 4. Simulated Coulomb stress changes for a normal faulting regime related to thermal contraction on the Tegelen fault after 2 years of continuous circulation of the CWG doublet. A circulation rate of 250 m³/hrs has been assumed. Stress magnitudes are colour-scaled. The well trajectories are depicted as red (GT01, production) and blue (GT03, reinjection) lines. In the SHA, normal faulting as well as strike-slip faulting have been considered, both resulting in comparable stress magnitudes but different spatial patterns. The black arrow denotes the Northern direction. Coordinates with respect to x = 204,042, y = 380,050 (RD). Modified figure from Vörös et al. (Reference Vörös, Baisch and Stang2015b).

For the ‘extreme scenario’, an ad hoc assumption was made that already smallest stress perturbations of $\Delta CS \ge $ 0.06 MPa may trigger seismicity. Furthermore, it was assumed that the fault is half a stress drop away from stress criticality. Based on the numerical simulations of stress changes (see above), the scalar seismic moment of induced seismicity was estimated from the continuous fault area subjected to stress load with $\Delta CS \ge $ 0.06 MPa. Seismic moment was converted to earthquake magnitude using the magnitude definition of Hanks & Kanamori (Reference Hanks and Kanamori1979).

Since no seismicity was detected during the previous 1.5 years of geothermal production, it was considered unlikely that fluid overpressure would cause seismicity in the future if the geothermal doublet was operated at the same production rate. This conclusion was based on the numerical model (see appendix) indicating that quasi-stationary hydraulic conditions were reached already after 2 weeks of continuous geothermal production. It should be noted that the numerical model did not account for the temperature dependency of the fluid viscosity. The impact of temperature-dependent fluid parameters, however, was assumed to be small compared to, for example, the observed injectivity increase of the injection well.

While fluid overpressure was not considered a relevant factor for causing seismicity, thermo-elastic stresses on the Tegelen fault were identified as a potential issue if the rocks at reservoir level deform seismically. These stresses could result from the cold water injection close to the Tegelen fault and accumulate over time. The simulated seismicity response for the ‘extreme scenario’ shows a systematic increase of the maximum magnitude over time, reaching the level of M_w = 2 after approximately 2 years of continuous operation (Fig. 5).

Fig. 5. Potential magnitude increases with time related to Coulomb stress changes on the Tegelen fault (compare Fig. 4). It is conservatively assumed that a continuous patch on the fault, subjected to stress perturbations above the critical threshold of ΔCS = 0.1 MPa, fails simultaneously. Figure from Vörös et al. (Reference Vörös, Baisch and Stang2015b).

Thermo-elastic stresses simulated for other mapped faults were much smaller due to their larger distance from the injection well. The level of $\Delta CS \ge $ 0.06 MPa is only reached on the Tegelen fault.

For limiting earthquake strength, real-time monitoring with a traffic light protocol (TLP, Bommer et al., Reference Bommer, Oates, Cepeda, Lindholm, Bird, Torres, Marroquín and Rivas2006) was recommended as a risk mitigation measure (Table 3). The TLP was designed to prevent the occurrence of an earthquake causing even slightest material damage. The metric of the proposed TLP was peak ground velocity (PGV), which was related to material damage through engineering standards (SBR, 2010). A ‘red light’ threshold value of PGV = 0.3 mm/s was thus defined for stopping operations. This threshold corresponds to the lower level of human perceptibility and is by a factor of 10 lower than the level at which damage to (sensitive) buildings is considered possible (SBR, 2010). Implementing such a large safety margin was deemed necessary to account for typical trailing effects, where the strongest earthquakes occur post-operation (see Baisch et al., Reference Baisch, Koch and Muntendam-Bos2019 for a more recent discussion).

Table 3. Traffic Light Protocol (TLP) for the Californië geothermal system. The TLP is based on peak ground velocities (PGV) measured at the surface. A stop of operations (‘red light’) is triggered in case ground vibrations exceed the level of human perceptibility. This threshold value accounts for a potential increase of earthquake strength after stopping operations (‘trailing effect’) such that minor damage to building is avoided.

The injectivity of the GT03 well had systematically improved during the 1.5 years of previous geothermal production, indicating that flow paths in the reservoir may have changed. For example, fracture permeability may have improved locally due to fracture cleaning. To ensure the applicability of the hazard assessment, a pressure monitoring focusing on increasing pressure at constant flow rates was suggested as an additional mitigation scheme. Furthermore, a re-evaluation of the seismic hazard was recommended in case of new data and/or if operational parameters deviate from the range considered in the seismic hazard assessment.

SHA#2 (CLG, August 2015)

After the first geothermal doublet (CWG doublet) went into operation, planning for a second geothermal doublet nearby was commenced by a different operating company (CLG doublet). Extending the geothermal system was considered a delicate subject as stress interferences of the two doublet systems were expected due to their proximity. Prior to drilling the CLG wells, a seismic hazard assessment was performed for the CLG doublet. This SHA also accounted for stress contributions from the existing CWG doublet (Vörös et al., Reference Vörös, Baisch and Stang2015a).

The seismic hazard assessment followed the same approach as outlined in the previous section. Different geological interpretations of the two operators were synchronised within a simplified numerical model for simulating hydraulic pressure changes associated with the simultaneous operations of the two geothermal doublets.

Fig. 6 shows hydraulic overpressure for a production scenario in which both doublets are operated simultaneously. Pressure changes with $\Delta p_{fl}$ = 0.1 MPa (equivalent to the assumed level above which seismicity can be triggered, Equation 1) are not observed at the Tegelen fault, but at the Velden fault to the north-east. Given the low level of overpressure, the potential for causing seismicity by pressure changes on the Velden fault was still considered low.

Fig. 6. Numerical model (left) and simulated fluid pressure changes Δp_fl in the reservoir layer for a production scenario with the two doublet systems (right). Grey surfaces (left) show the aquifer and the Tegelen fault of the numerical model. Pressure changes shown after 190 days of continuous operation at a rate of 310 m³/hrs. Isobars are depicted in red, reservoir faults in grey, main faults are labelled. Arrow indicates Northern direction. Coordinates with respect to x = 204,042, y = 380,050 (RD). Modified figure from Vörös et al. (Reference Vörös, Baisch and Stang2015a).

Simulation of the stress changes caused by thermal contraction resulting from CLG production yielded minor stress changes on the mapped faults. These changes were considered to be too small to cause seismicity.

Incorporation of the cooling stresses resulting from the CWG injector (compare previous section) and the possibility of an unmapped, critically stressed fault in the vicinity of the CLG injector, resulted in the recommendation of seismic real-time monitoring with a TLP as a risk mitigation measure. The proposed TLP was based on the same threshold values as for the CWG doublet system (Table 3), while a red stoplight now implied the shutdown of both doublets.

SHA#3 (CLG update, March 2018)

The seismic hazard assessment for the CLG doublet was updated after drilling and testing the CLG wells (Vörös et al., Reference Vörös, Baisch and Stang2015b). Subsurface stress perturbations were simulated utilising a revised reservoir model with a modified geometry. Hydraulic conductivities had to be reduced to stay consistent with well-testing results. Consequently, simulated overpressure on the Velden fault slightly increased in the updated simulations. The simulations revealed that quasi-stationary conditions had already been reached during the previous well tests, which were not associated with measurable seismicity. Therefore, overpressure causing seismicity was considered unlikely if circulation rates were not to be increased.

Thermo-elastic stresses on the mapped faults (located beyond the cooled zone) were numerically simulated using the approach outlined in SHA#1. Sensitivity tests have shown that thermal contraction stresses are relatively insensitive to the geometrical details of the cooled zone as long as the faults are sufficiently far away from the cooling front. Therefore, it was concluded that the modified reservoir model had no significant impact on the outcome of previous simulations of stress perturbations resulting from thermal contraction.

Earthquake interpretation study, February 2019

Following an earthquake sequence in September 2018, a detailed study was conducted to investigate the cause of the earthquakes and their relation to the two geothermal doublets (Baisch & Vörös, Reference Baisch and Vörös2019). Hypocenter locations were determined with a linearised inversion scheme based on P- and S-phase arrival times (Baisch et al., Reference Baisch, Bohnhoff, Ceranna, Yimin and Harjes2002). Epicentre locations determined with the initial (uncalibrated) seismic velocity model clustered near the CWG doublet with an isolated earthquake near the CLG injection well (Fig. 7). Hypocentral depth was estimated around 6 km. This depth was interpreted to result from the uncalibrated velocity model. Based on the immediate response of the seismicity to production rate changes and excluding natural causes, it was speculated that the earthquakes were more likely located shallower, in the depth range from 2.5 to 3.0 km and thus within the range of stress perturbations from the geothermal system.

Fig. 7. Absolute hypocentre location in map view. Error bars show the location accuracy with a 2σ confidence level (formal inversion error). Triangles denote the location of the seismic monitoring stations. Events were colour-coded according to the time of occurrence (see legend). The grey patch depicts the Tegelen fault. The magenta lines show the well trajectories of GT01, GT03, GT04 and GT05, respectively. Black arrow indicates Northern direction. Coordinates with respect to x = 204,042, y = 380,050 (RD). The first six events occurred prior to production start of the CLG doublet. Event hypocentres are depicted as determined for the SHA before the modification of the velocity model. Figure from Baisch & Vörös (Reference Baisch and Vörös2019).

To evaluate the stress impact of the two doublet systems separately, the six earthquakes occurring prior to CLG operation were investigated. It was noted that these earthquakes systematically occurred after the CWG production rate was either reduced or production was stopped. This hypothesis was tested using a simple mathematical model comparing the production rate Q(t _i ) at the time t _i when the i’th earthquake occurred with the average production rate QAV _i prior to the earthquake. The mean flow rate prior to earthquake i was defined as

(2) $${\rm QAV_i}\left( T \right) = \;{{\mathop \int \nolimits_{ti - T}^{ti} Q\left( t \right)dt} \over T}$$

with T denoting the time window length over which the flow rate is averaged. Furthermore, the parameter

(3) $${k_i}\left( T \right) = {{Q\left( {{t_i}} \right)} \over {\rm QAV_i}\left( T \right)} $$

was defined to compare the production rate at the time of the earthquake to the previous, averaged production rate. To avoid bias from production rate variations close to zero, production data were rounded towards 10 m³/hrs bins. Moreover, the numerical resolution limit (10⁻¹⁶) was added to the average rate QAV _i (T) to obtain k _i = 0 in case Q _i = 0 and QAV _i (T) = 0. If earthquake timing truly correlates with negative production rate changes, k _i is systematically smaller than 1. Indeed, this was found for the 6 earthquakes occurring at a time when only the CWG doublet system was operated. Fig. 8 shows k _i as a function of window length T. Two events occurred during shut-in (i.e. Q _i = 0). These events exhibit a k _i = 0, independent of T. For the remaining four events, k _i is close to 1 for small T (approximately < 1.2 days) reflecting the delay time between rate changes and earthquake occurrence. For larger T, k _i is generally smaller than 1.

Fig. 8. Ratio between production rate Qi at the occurrence time of seismic event i and the average rate QAV prior to the event as a function of time length T over which the production rate is averaged. The ratio is shown for all six seismic events occurring between 31 August 2014 (begin of seismic monitoring) and 31 May 2017 (begin of CLG production). Earthquakes occurring during shut-in (Q_i = 0) show up as a flat line. Note: In a diffusion-type triggering model, delay times can vary even if all earthquakes occurred at the same location. Delay times are sensitive to the specific triggering level of each event. Modified figure from Baisch & Vörös (Reference Baisch and Vörös2019).

In a subsequent step, synthetic earthquake catalogues were used to investigate the probability of a coincidental correlation between production rate changes and earthquake occurrence time. 100,000 synthetic catalogues were compiled, each containing six earthquakes with an occurrence time sampled from a uniform random distribution. The rate at which the synthetic catalogues exhibit k _i (T) smaller than observed was found to be in the order of 1e⁻³ and 1e⁻⁴. Therefore, a coincidental correlation between earthquake occurrence and CWG activities can be excluded at a high confidence level. Consequentially, changes of the hydraulic fluid pressure Δp _fl were identified as the triggering mechanism for the 6 seismic events under consideration.

A conceptual explanation was proposed. In this model, the Tegelen fault was loaded by Coulomb stresses resulting from thermal reservoir contraction due to cold water injection close to the fault. These stresses were interpreted to be the root cause for the earthquakes. During production, fluid pressure on the Tegelen fault was lowered. This resulted in higher effective normal stresses $\Delta\sigma _{n,eff} = \Delta \sigma _{n}- \Delta p_{fl}$ , stabilising the fault. At the lowered pressure conditions during production, the Tegelen fault was further loaded by additional thermal contraction stresses without becoming overcritical. In the proposed model, stress criticality and seismic failure occurred post-production when the in situ pressure in the Tegelen fault returned to equilibrium state. At that time, effective normal stresses were decreasing (thus destabilising the fault), while the additional stress load from thermal contraction remained.

Simple numerical simulations were performed to test the validity of the proposed mechanism. These simulations focussed on the triggering process and the associated timing of the earthquakes in response to changes in production history rather than attempting to model absolute pressure levels.

For example, Fig. 9 shows a simulated pressure evolution inside the Tegelen fault at 5 km depth. The timing of the earthquakes coincides with the sharp pore pressure build-up following shut-in. The level of pressure changes is very small in this model. At reservoir depth, pressure changes are larger but still imply earthquake triggering at a very low level of stress changes.

Fig. 9. Evolution of simulated fluid pressure changes in the Tegelen fault at a depth of 5 km. This conceptual model aims to explain the mechanism causing induced seismicity during time periods of reduced rates or shut-in. The model consists of a simple reservoir layer intersecting the Tegelen fault. Occurrence times of the seismic events (18-Aug 2015, 5-Dec 2015 and 26-Jan 2016) are marked by black arrows. Figure from Baisch & Vörös (Reference Baisch and Vörös2019).

The proposed model provided an explanation for the earthquakes occurring prior to the operation of the second doublet. The simultaneous operation of both doublets after September 2017 impeded an establishment of causal relations for the later events. It was noted, however, that the subsequent earthquake (occurring 8-4-2018) exhibited the same correlation with rate reduction at CWG while both doublets were operational.

The sequence of earthquakes in September 2018 occurred after the shutdown of both geothermal doublets. Relative hypocentre locations were determined indicating that these earthquakes occurred almost at the same location where the previous seismicity related to CWG production had occurred. By combining the observed spatial and temporal correlations, the study concluded that all but one earthquake was likely related to production at the CWG well.

The remaining earthquake (M = 0, 25-8-2018) was located further North in the vicinity of the CLG injection well. It was concluded that this earthquake could have been caused by CLG production but contributions from CWG production were also considered possible. With hindsight, it should be noted that the earthquake in question was shifted onto the Tegelen fault after re-locating hypocentres (see section on Hypocenter Relocation).

SHA CLG update, March 2019

As part of the permit application process for resuming production of the CLG doublet, the seismic hazard assessment for the CLG doublet was updated (Vörös & Baisch, Reference Vörös and Baisch2019). The study focused on the seismic hazard associated with resuming production at the CLG doublet with a decommissioned CWG doublet. This update followed the same approach used in the previous studies accounting for the seismicity observations and interpretations outlined in the Earthquake interpretation study (previous section).

It was concluded that resuming geothermal production at the CLG doublet will most likely not cause seismicity on the known faults. This conclusion was drawn based on the assumption that injection into the GT03 well, identified as the root cause for seismicity, will not resume.

The same TLP used in previous studies (Table 3) was proposed for limiting the strength of earthquakes potentially occurring on an unmapped fault. Given that the cause for one of the earthquakes was considered unclear (see previous section), it was recommended to stop production if an earthquake, independent of its magnitude, is detected near the CWG injector. The reasoning was that such an earthquake would indicate that seismicity can be triggered by extremely small stress perturbations, smaller than considered in the study. In that case, a re-assessment prior to recommencing production was deemed necessary as such extremely small stress changes were not taken into account in the study.

With these mitigation measures in place, the mitigated risk was considered to be acceptable.

Hypocenter relocation, January 2021

In a recent study, we have re-located hypocentres based on a seismic wave velocity model calibrated with recordings of several perforation shots fired in the well GT04 (de Pater, Reference de Pater2021). This perforation shot data were not considered previously as the shot time was not measured. To account for an unknown shot time, we have designed a new calibration procedure based on differential travel times between S-wave (t _S) and P-wave (t _P)_, which are independent of the shot time. Let v _P and v _S denote the compressional and shear wave velocities, and Δ the source-receiver distance, then

(4) $$t_S - t_P = t_0 + \Delta /v_S - t_0 - \Delta /v_P = \Delta /v_S - \Delta /v_P$$

Rearranging yields

(5) $$\Delta = v_P*v_S/(v_P - v_S)*(t_S - t_P)$$

In our approach, the mixed velocity term v _P·v _S / (v _P-v _S) was calibrated and subsequently used for re-locating the earthquakes using a linearised inversion (e.g. Baisch et al., Reference Baisch, Bohnhoff, Ceranna, Yimin and Harjes2002).

Re-located hypocentres aligned along the Tegelen fault close to the CWG wells approximately at reservoir depth (Fig. 10). Interestingly, also the most northern earthquake was consequently shifted towards the Tegelen fault. The cause of this earthquake, however, remained speculative.

Fig. 10. Re-located seismicity, based on the reviewed velocity model (black dots) and re-simulated thermal contraction stress changes ΔCS on the Tegelen fault. The view from South-West (left) and from top (right) is shown. Stress changes are colour-scaled in MPa according to the colour bar. The accumulated stresses have been re-simulated for May 2018, after the CWG doublet stopped operations. Simulations were based on the actual flow rate. Stresses were computed assuming a strike-slip failure regime. The resulting stress pattern coincides spatially with the re-located hypocentres of the events. The colour map is saturated at a value of 0.1 MPa. Maximum stress values of >0.3 MPa are obtained locally. Trajectories of the GT01 and GT03 wells are depicted as red and blue lines, respectively. The Northern direction is indicated by a black arrow. Coordinates with respect to x = 204,042, y = 380,050 (RD).