Litcius/Paper detail

De-risking the energy transition by quantifying the uncertainties in fault stability

David Healy, Stephen Hicks

2022Solid Earth22 citationsDOIOpen Access PDF

Abstract

Abstract. The operations needed to decarbonize our energy systems increasingly involve faulted rocks in the subsurface. To manage the technical challenges presented by these rocks and the justifiable public concern over induced seismicity, we need to assess the risks. Widely used measures for fault stability, including slip and dilation tendency and fracture susceptibility, can be combined with response surface methodology from engineering and Monte Carlo simulations to produce statistically viable ensembles for the analysis of probability. In this paper, we describe the implementation of this approach using custom-built open-source Python code (pfs – probability of fault slip). The technique is then illustrated using two synthetic examples and two case studies drawn from active or potential sites for geothermal energy in the UK and discussed in the light of induced seismicity focal mechanisms. The analysis of probability highlights key gaps in our knowledge of the stress field, fluid pressures, and rock properties. Scope exists to develop, integrate, and exploit citizen science projects to generate more and better data and simultaneously include the public in the necessary discussions about hazard and risk.

Topics & Concepts

Induced seismicityGeothermal gradientExploitSeismic hazardGeothermal energyPython (programming language)SeismologyMonte Carlo methodSlip (aerodynamics)GeologyComputer scienceRisk analysis (engineering)EngineeringGeophysicsComputer securityMathematicsStatisticsBusinessAerospace engineeringOperating systemearthquake and tectonic studiesCO2 Sequestration and Geologic InteractionsSeismology and Earthquake Studies