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Details of Award

NERC Reference : NE/S003886/1

Geothermal Power Generated from UK Granites (GWatt)

Grant Award

Principal Investigator:
Dr R Shail, University of Exeter, Camborne School of Mines
Co-Investigator:
Dr M Eyre, University of Exeter, Earth and Environmental Science
Science Area:
Earth
Overall Classification:
Unknown
ENRIs:
Natural Resource Management
Science Topics:
Earth Engineering
Fluid flow
Geochemistry
Geothermal energy
Microseismicity
Rock fracture
Earth Resources
Faulting
Geomechanics
Geothermal energy
Heat exchange
Hydrothermal fluids
Survey & Monitoring
Abstract:
Decarbonising power generation is a challenge for the UK, requiring an 80% reduction in greenhouse gas emissions by 2050, relative to 1990 levels. Carbon-free, renewable sources are attractive, but wind and solar generation are intermittent. In contrast, geothermally generated electricity is available all the time (i.e. is 'base load'). In the UK this can be developed with Engineered Geothermal Systems (EGS) whereby very hot water is accessed from depth via deep boreholes (4km or more) and is used to drive a turbine. Pioneering research has shown that permeable rocks (those through which fluid can flow) at depth are often associated with natural fracture systems. However, exploitation of the UK underground thermal resource has been held back by; 1) knowledge gaps about permeability and fluid/heat flow within the fractured hot rocksand 2) a perception that the uncertainty associated with drilling problems or limited fluid flow from deep boreholes are too high for the potential financial reward. This project, Geothermal Power Generated from UK Granites (GWatt), seeks to address these barriers to uptake of EGS by: - Increasing knowledge of the geological conditions needed for deep fracture-controlled fluid flow within granitic rocks. - Developing a quantitative understanding of the heat resource and sustainability of the geothermal reservoir. - Constructing robust geological risk assessments based on well-established oil & gas uncertainty quantification and optimisation methods, with a view to reducing perceived risks. - Applying the integrated results of site-specific research to new geothermal exploration models for other granites, particularly those in SW England. A particular strength of GWatt is the link with the developing United Downs Deep Geothermal Power (UDDGP) project, an #18M, 2 borehole EGS in the Carnmenellis granite in Cornwall. This will provide a unique resource; downhole fluids, rock samples, geophysical logs, flow data and seismic data. GWatt will maximise the scientific potential from these data, and carry out innovative further analyses and interpretation, combining site-specific observations with regional studies and state-of-the-art uncertainty quantification, to address the challenges associated with EGS development within SW England. Other UK crystalline basement rocks show fracture-controlled groundwater flow, so the lessons learned from GWatt will ultimately benefit understanding of the rest of the UK deep subsurface. The project consortium comprises research, business and local government partners. The British Geological Survey, the University of Exeter Camborne School of Mines and Heriot Watt University provide complimentary skills in deep geothermal resource assessments, deep fracture fluid flow, rock/fluid interactions, reservoir modelling, detailed knowledge of the geology of SW England and the quantification of geological uncertainties. Geothermal Engineering Ltd. and Geoscience Ltd. are developing the UDDGP project and provide a wealth of experience delivering UK geothermal projects. Computer Modelling Group Ltd. will provide advanced heat and fluid flow modelling software. The Cornwall and Isles of Scilly Local Enterprise Partnership and Cornwall Council will facilitate outreach and dissemination activities, both to local people and the business community. Beneficiaries include local communities through the creation of EGS combined heat and power plants that will be important hubs for renewable energy networks, supplying carbon-free heat and power. The heat can be used for space heating, industrial drying, balneology, greenhouse heating, fish farms etc., all of which will generate local jobs. Local industry will also benefit from the regional scale uptake of EGS within SW England and a potential revival of the minerals industry arising from technological solutions to extracting metals from the deep geothermal brines.
Period of Award:
2 Jan 2019 - 1 Jul 2023
Value:
£434,309 Split Award
Authorised funds only
NERC Reference:
NE/S003886/1
Grant Stage:
Completed
Scheme:
Directed (Research Programmes)
Grant Status:
Closed
Programme:
Highlights

This grant award has a total value of £434,309  

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FDAB - Financial Details (Award breakdown by headings)

DI - Other CostsIndirect - Indirect CostsDA - InvestigatorsDI - StaffDA - Estate CostsDI - T&SDA - Other Directly Allocated
£29,094£154,249£36,951£120,487£56,591£23,225£13,712

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