An integrated geological evaluation of the Lower Triassic Main Buntsandstein sandstones for deep geothermal applications in the southern Netherlands – HotTrias project

Emilio Cecchetti, Allard W. Martinius, Marita Felder, Marinus E. Donselaar, Annelies Bender, Giovanni Bertotti, Pierre-Olivier Bruna, Hemmo A. Abels

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Abstract

Sandstones from the Main Buntsandstein Subgroup represent a promising deep geothermal target in the subsurface of the Netherlands considering their widespread distribution and temperatures locally reaching 140-150 °C at depths of ~ 3 to 5 km. The Main Buntsandstein Subgroup is a sand-prone interval, but the reservoir quality of these sandstones is known to be heterogeneous as result of an interplay between depositional and diagenetic processes. This makes the Buntsandstein sediments an uncertain and risky geothermal play.

In this project, we assess the syn- and post-depositional history of these sediments. The aim is to define structural, sedimentary, and diagenetic heterogeneities within the Main Buntsandstein sediments and assess their impact on reservoir quality. This will help reduce uncertainties for geothermal operations in the Triassic in the southern Netherlands and beyond.

The structural analysis of the study area using seismic and well data reveals that the Main Buntsandstein sediments represent an early syn-rift sequence and that their present-day distribution is strongly controlled by faulting. In parallel, the study of the sedimentology and stratigraphy conducted on core and wireline data indicates that the depositional environment evolves through the Buntsandstein stratigraphy, resulting in the development of different reservoir architectures. Diagenesis has largely altered the primary relationship between sedimentary facies and porosity and permeability. Overall cementation seems to have a larger impact on reducing reservoir quality than compaction, with quartz, dolomite, and illite representing the most abundant types of cement. The analysis of fractures using core and image logs suggests that the fracture density is driven by the lithological variability within the Main Buntsandstein and that fracture joints and stylolites locally may contribute to enhancing the system permeability.

The integrated assessment of the results allows the development of prospect play maps for the Buntsandstein in the southern Netherlands, addressing uncertainties and providing future recommendations for further exploration and optimizing geothermal operations in the Triassic.
Original languageEnglish
Number of pages1
Publication statusPublished - 2024
EventEuropean Geothermal PhD Days 2024 - X building, TU Delft Campus, Delft, Netherlands
Duration: 3 Apr 20245 Apr 2024
https://www.egpd2024.com/

Conference

ConferenceEuropean Geothermal PhD Days 2024
Abbreviated titleEGPD 2024
Country/TerritoryNetherlands
CityDelft
Period3/04/245/04/24
Internet address

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