Hostname: page-component-76d6cb85b7-dqfph Total loading time: 0 Render date: 2026-07-15T07:54:15.583Z Has data issue: false hasContentIssue false

Induced seismicity and seismic risk management – a showcase from the Californië geothermal field (the Netherlands)

Published online by Cambridge University Press:  19 July 2022

Robert Vörös*
Affiliation:
Q-con GmbH, 76887 Bad Bergzabern, Germany
Stefan Baisch
Affiliation:
Q-con GmbH, 76887 Bad Bergzabern, Germany
*
Author for correspondence: Robert Vörös, Email: voeroes@q-con.de

Abstract

Two closely spaced geothermal doublets were operated in the Californië geothermal field near Venlo, the Netherlands. The geothermal wells target the Dinantian Zeeland formation below 2 km depth. For several years, hot fluid was produced from the Tegelen fault, a regional fault in the Roer Valley rift system, until a felt M1.7 earthquake led to the suspension of geothermal activities. The Californië showcase provides a rare opportunity to retrospectively evaluate the assessment and the management of induced seismicity risks for a geothermal project. A seismic hazard assessment was conducted at several stages of the project, and seismicity was continuously monitored with a local station network.

In this paper, we report on the characteristics of the induced seismicity and evaluate the findings of the seismic hazard assessments conducted prior to the earthquakes. Seismic hazard assessments were based on numerical simulations of subsurface stress changes associated with geothermal operations. A geomechanical analysis indicated that the mapped faults in the subsurface are likely to be critically stressed. The largest hazard was inferred to result from thermo-elastic stresses, originating from cold water injection close to the Tegelen fault.

Subsequent earthquakes predominantly occurred near a production well after stopping or reducing production. We attributed this observation to a thermo-elastic stress load caused by cold water injection close to the Tegelen fault, combined with a counter-acting stabilisation of the fault due to pressure depletion during production. This mechanism was consistent with the dominating mechanism considered in the preceeding seismic hazard assessments. Although geothermal operations have not resumed yet, the geomechanical analysis indicates that re-locating one of the injection wells further away from the Tegelen fault could provide an efficient measure for mitigating induced seismicity risks at Californië.

Information

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided that no alterations are made and the original article is properly cited. The written permission of Cambridge University Press must be obtained prior to any commercial use and/or adaptation of the article.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of the Netherlands Journal of Geosciences Foundation
Figure 0

Fig. 1. Left: Location of the Californië geothermal project (red square) and main structural elements of the Roer Valley Rift System. Earthquake epicentres (KNMI-catalogue as of 2015 when the first SHA was conducted) are plotted as open circles scaled by magnitude (magnitude range M = −0.1 to M = 5.8). Right: Zoomed in section around the red square showing well trajectories of the CWG / CLG doublets (coloured lines) and fault trajectories at the top of the Carboniferous limestone group (black lines). Fault trajectories were derived from seismic interpretations and implemented into the numerical model accordingly. The major Tegelen fault extends farther than the seismic mapping indicates (dashed lines). Labelled lines indicate top reservoir depth level (in m). The grey-shaded zone denotes the extension of the Tegelen fault with depth. The Black arrow points in the Northern direction. RD (Rijks-Driehoek) coordinate system used. The red dashed line denotes the location of the vertical section as shown in Fig. 2. Modified figures from Vörös et al. (2015b).

Figure 1

Fig. 2. Production (red, either CWG or CLG) and injection wells (blue: CWG, light blue: CLG) in a schematic geological cross-section from West to East through the project area. The location of the cross-section is outlined in Fig. 1 (red dashed line, not the same scale). The doublets are offset perpendicular to the drawing plane. The trajectories of the production wells penetrate the Tegelen fault. The injection well of the CWG doublet was originally drilled into the Tegelen fault but subsequently got blocked. Fluid was reinjected through a slotted liner into the reservoir formation at a depth range between 1800 and 2050 m (blue). The trajectory of the CLG reinjection well is directed away from the Tegelen fault. The geothermal aquifer comprises the Graben-related Tegelen fault zone and the Dinantian Zeeland formation (Kolenkalk Group). Modified figure from Vörös et al. (2015b).

Figure 2

Fig. 3. Measured flow rate (top) and wellhead pressure (bottom) at the reinjection wells GT03 (CWG, black) and GT05 (CLG, orange). The CWG doublet started production already at the end of 2013. Data, however, are only available after January 2014.The occurrence of induced earthquakes is denoted by black circles scaled by magnitude (top). The red dashed line denotes the occurrence time of the felt earthquake on 3 September 2018. The felt event is the largest event (large circle) and is the third event within a cluster of events between 3 September and 9 September. The timeline of seismic monitoring and studies performed related to the seismic hazard at the site is indicated at the top of the figure. Modified figure from Baisch & Vörös (2019).

Figure 3

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.

Figure 4

Table 2. Parameter for the computation of thermal stresses.

Figure 5

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. (2015b).

Figure 6

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. (2015b).

Figure 7

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.

Figure 8

Fig. 6. Numerical model (left) and simulated fluid pressure changes Δpfl 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. (2015a).

Figure 9

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 (2019).

Figure 10

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 (Qi = 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 (2019).

Figure 11

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 (2019).

Figure 12

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).

Figure 13

Table 4. Parameter for the hydraulic model used in the first two SHAs. The segmentation of the aquifer into two conductive and one intermediate, tight part reflects the identification of two major fluid loss zones at the CWG injection well. Both models differ in terms of the geometry, as the second model also includes the CLG-doublet and was extended in the Northern direction.

Figure 14

Table 5. Parameter used in the generic model of a geothermal doublet.

Figure 15

Fig. 11. Analytic solutions for the cooling front in a generic, homogeneous aquifer (after Schulz, 1987), displayed in a horizontal section at the centre of the reservoir layer. The cooled rock volume was simulated for different times after the start of the circulation according to the parameters in Table 5. The size of the elementary Okada sources is outlined for each time step by a red rectangle. Blue arrows indicate displacement directions outside the cooled zone, normalised for each time step. Black line denotes the trajectory of a fault located outside the cooled zone. Temperature decay with respect to the initial reservoir temperature according to the colour scale.

Figure 16

Fig. 12. Comparison of the Finite Element solution for thermal contraction stresses (Coulomb stress changes assuming a left lateral strike-slip failure mechanism) on a nearby fault with approximate solutions utilising Okada elementary sources. Approximation sources extend in the vertical direction over the complete reservoir layer. A segment of the cooled reservoir rock is approximated by three orthogonal, planar elementary sources, representing contraction of the volume in the three spatial directions. Approximation one utilises three elementary sources for the complete cooled rock volume with a lateral extension corresponding to the red rectangles as shown in Fig. 11. Approximation two consists of a larger number of elementary sources with a side length of 20 m, approximating the spatial shape of the cooled rock area shown in Fig. 11. Stress magnitudes according to the colour scale saturated at the minimum and maximum stresses for the Finite Element solution at each time step. The x-axis indicates distance along the strike direction of the fault.