Characterising brines in deep Mesozoic sandstone reservoirs, Denmark

Hanne D. Holmslykke,Niels H. Schovsbo,Rikke Weibel,Lars Henrik Nielsen,Lars Kristensen

doi:10.34194/geusb-201943-01-04

Hanne D. Holmslykke, Niels H. Schovsbo + Show 3 more

Open Access

https://doi.org/10.34194/geusb-201943-01-04

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Journal: GEUS Bulletin	Publication Date: Jul 17, 2019
Citations: 4	License type: cc-by

Affiliation: Geological Survey of Denmark and Greenland

Abstract

The Danish subsurface contains several sandstone units, which represent a large geothermal resource (Vosgerau et al. 2016). Currently, only three geothermal plants are operating in Denmark, but several exploration licences are expected to be awarded in 2019. Geothermal energy is exploited from deeply buried porous sandstones by bringing warm formation water (brine) to the surface, extracting the heat and returning the cooled water to the same sandstones. The reduced temperature of the brine during this process implies a risk of scaling, which may reduce reservoir permeability and hence injectivity. Predicting the chemical composition of formation waters, however, could help to reduce the risk associated with scaling in planned geothermal facilities. Here, we present a regional overview of the geochemistry of brines from deep Mesozoic sandstones in the Danish Basin and North German Basin that supplements previous studies, notably by Laier (2002, 2008). The brine composition at shallow burial typically reflects the original (connate) formation water chemistry, which is determined by the original depositional environment of the sandstone, for example fluvial or marine. However, the mineralogical composition of the sandstone changes during burial, whereby some minerals may dissolve or precipitate when exposed to higher temperatures. These mineral changes are reflected in the brine composition, which typically becomes more saline with increased burial (e.g. Laier 2008; Kharaka & Hanor 2003).  The brine chemistry reported here shows a distinct depth trend, which reflects original connate formation waters that are modified through burial diagenesis. We have classified the brines into brine types, which are shown to be related to their depositional environment, depth, geological formation and geographical domains.

Highlights

The Danish subsurface contains several sandstone units, which represent a large geothermal resource (Vosgerau et al 2016)
We present a regional overview of the geochem istry of brines from deep Mesozoic sandstones in the Danish Basin and North German Basin that supplements previous studies, notably by Laier (2002, 2008)
To classify the brine types we applied a principal component analysis (PCA), which trans forms a matrix of measured data (X; comprised of N samples and P variables) into sets of projection subspaces delineated by principal components

Summary

Introduction

The Danish subsurface contains several sandstone units, which represent a large geothermal resource (Vosgerau et al 2016). Predicting the chemical composition of formation waters, could help to reduce the risk associated with scaling in planned geothermal facilities. The brine composi tion at shallow burial typically reflects the original (connate) formation water chemistry, which is determined by the origi nal depositional environment of the sandstone, for example fluvial or marine. The mineralogical composition of the sandstone changes during burial, whereby some min erals may dissolve or precipitate when exposed to higher tem peratures. These mineral changes are reflected in the brine composition, which typically becomes more saline with in creased burial The brine chemistry reported here shows a distinct depth trend, which reflects original connate formation waters that are modified through burial diagenesis. We have classified the brines into brine types, which are shown to be related to their depositional environment, depth, geological formation and geographical domains

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Results

Conclusion