PhD in Fractured Geothermal Reservoirs

In the global north, over 40% of the total energy consumption is used for heating and cooling of buildings. Geothermal energy has the potential to significantly decarbonise energy supplies not only for heating and cooling but also for electricity generation, and therefore make a major contribution to the transition to a sustainable and just low-carbon energy future.

Naturally occurring fractures often provide the primary permeability for fluid flow and heat transport in many geothermal reservoirs. However, predicting heat flow through fracture networks to assess the viability of a potential geothermal development is challenging due to the inherent uncertainties in the fracture network and its properties. To date, no systematic studies have aimed to establish the properties that fundamentally control the characteristics of heat flow in naturally fractured geothermal reservoirs. For example, it is unclear how the combination of hydraulic connectivity within the fracture network and the size of the less permeable matrix blocks impact heat flow, i.e., under which conditions heat flow in a fractured geothermal reservoir can be characterised by effective properties that approximate a single porosity system and when heat flow needs to be characterised by more complex approaches.

New data from outcrop analogues for fractured reservoirs (e.g., imagery from drones or lidar for geometric attribute identification), state-of-the-art numerical simulations that resolve fractures properly in reservoir models, and machine learning techniques now enable us to characterise the type of flow behaviours that can occur in fractured geothermal reservoirs and establish the links between fracture network properties and associated flow behaviours.

The hypothesis central to this PhD thesis is therefore that there is only a small number of heat flow behaviours in fractured geothermal reservoirs that can be correlated to a reasonably well constrained set of fracture network properties. More specifically, the PhD thesis aims to answer the following questions:

This PhD project is fully funded by Energi Simulation. The you will join a vibrant and internationally renowned department working across a wide range of geoenergy challenges, and become part of the department’s newly established Energi Simulation Centre for Geoenergy, benefitting from its extensive national and international research network. In this role you will receive extensive training in geothermal reservoir engineering, fluid flow in fractured geological formations, fracture network characterisation and modelling, machine learning, geothermal reservoir simulation, and how to present the research results at conferences and in peer-reviewed results. These skills will equip you with a unique set of skills to work on range of geoenergy challenges in major energy companies, consultancies, or in academic or national research centres.