TY - JOUR
T1 - Liverpool Land Basement High, Greenland: Visualising inputs for fractured crystalline basement reservoir models
AU - Banks, Graham
AU - Bernstein, Stefan
AU - Salehi, Sara
AU - Guarnieri, Pierpaolo
AU - Bird, Dennis
AU - Hamblett, Catherine
AU - Peacock, David
AU - Foster, Jon
PY - 2019/7/22
Y1 - 2019/7/22
N2 - Basement highs are large structural features, commonly buried in
sedimentary basins (Busby & Azor 2012). They are of interest for
natural resources exploration and research because of their ability to
influence migration and entrapment of petroleum (Trice 2014) and water,
and the deposition of metals (Hitzman 2005; Borg et al. 2012).
Three-dimensional (3D) reservoir models (e.g. Shepherd 2009) are built
to evaluate and model fluid-filled basement reservoirs (Ringrose &
Bentley 2015). However, subsurface data are expensive, difficult to
obtain and are often widely spaced. Ideally, basement reservoir models
would be constrained by rock, fracture and mineral vein data from
appropriate outcrop analogues (acknowledging that subaerial basement
rocks have, by definition, a different uplift history than subsurface
basement). The Liverpool Land Basement High (LLBH) in Greenland is an
uplifted and well-exposed basement high located between two sedimentary
basins, and thus provides a valuable analogue for fractured
basement-hosted mineral, oil and geothermal reservoirs.
The Geological Survey of Denmark and Greenland (GEUS) conducted
reconnaissance work on the LLBH in 2018 to assess the quality of the
exposure of basement palaeo-weathering profiles and fault-fracture
networks. Here, we introduce the LLBH, the concept of fractured basement
reservoir modelling, and how studying the LLBH can help enhance
reservoir modelling of fractured basement. We present some of our
preliminary observations of LLBH fault-fracture networks and discuss how
the exposed sediment-basement features and processes might aid
industry and research in their top basement mapping activities. We
propose that LLBH provides a particularly suitable analogue for industry
and research to analyse: (a) multiscale fracture system connectivity,
(b) fluid migration and fluid-rock reaction processes, (c) input
parameters for basement reservoir modelling and (d) top basement
geomorphologies and processes.
AB - Basement highs are large structural features, commonly buried in
sedimentary basins (Busby & Azor 2012). They are of interest for
natural resources exploration and research because of their ability to
influence migration and entrapment of petroleum (Trice 2014) and water,
and the deposition of metals (Hitzman 2005; Borg et al. 2012).
Three-dimensional (3D) reservoir models (e.g. Shepherd 2009) are built
to evaluate and model fluid-filled basement reservoirs (Ringrose &
Bentley 2015). However, subsurface data are expensive, difficult to
obtain and are often widely spaced. Ideally, basement reservoir models
would be constrained by rock, fracture and mineral vein data from
appropriate outcrop analogues (acknowledging that subaerial basement
rocks have, by definition, a different uplift history than subsurface
basement). The Liverpool Land Basement High (LLBH) in Greenland is an
uplifted and well-exposed basement high located between two sedimentary
basins, and thus provides a valuable analogue for fractured
basement-hosted mineral, oil and geothermal reservoirs.
The Geological Survey of Denmark and Greenland (GEUS) conducted
reconnaissance work on the LLBH in 2018 to assess the quality of the
exposure of basement palaeo-weathering profiles and fault-fracture
networks. Here, we introduce the LLBH, the concept of fractured basement
reservoir modelling, and how studying the LLBH can help enhance
reservoir modelling of fractured basement. We present some of our
preliminary observations of LLBH fault-fracture networks and discuss how
the exposed sediment-basement features and processes might aid
industry and research in their top basement mapping activities. We
propose that LLBH provides a particularly suitable analogue for industry
and research to analyse: (a) multiscale fracture system connectivity,
(b) fluid migration and fluid-rock reaction processes, (c) input
parameters for basement reservoir modelling and (d) top basement
geomorphologies and processes.
UR - http://www.scopus.com/inward/record.url?scp=85078470401&partnerID=8YFLogxK
U2 - 10.34194/GEUSB-201943-02-04
DO - 10.34194/GEUSB-201943-02-04
M3 - Article
SN - 2597-2154
SN - 1904-4666
SN - 1604-8156
VL - 43
JO - Geological Survey of Denmark and Greenland Bulletin
JF - Geological Survey of Denmark and Greenland Bulletin
M1 - e2019430204
ER -