et_stenille
Differences
This shows you the differences between two versions of the page.
| Both sides previous revisionPrevious revisionNext revision | Previous revision | ||
| et_stenille [19/06/2023 09:53] – mike_gss | et_stenille [19/06/2023 12:07] (current) – mike_gss | ||
|---|---|---|---|
| Line 1: | Line 1: | ||
| - | ==== The Stenlille | + | ==== The Stenlille |
| + | |||
| + | {{: | ||
| + | |||
| + | //Seismic survey acquisition: | ||
| Denmark is one of the world leaders in the Energy Transition with current focus on CCUS (Carbon Capture, Utilization and Storage). | Denmark is one of the world leaders in the Energy Transition with current focus on CCUS (Carbon Capture, Utilization and Storage). | ||
| - | Hydrocarbons have been extracted from beneath the Danish sector of the North Sea for decades, but earlier this year (2023), for the first time in the southern North Sea, captured CO2 was pumped back into a depleted Danish oil field; Nini West. ([[https:// | + | Hydrocarbons have been extracted from beneath the Danish sector of the North Sea for decades, but earlier this year (2023), for the first time in the southern North Sea, captured CO2 was pumped back into a depleted Danish oil field; Nini West. (see [[https:// |
| Onshore Denmark, natural gas has been successfully and safely stored for around 30 years in the Stenlille structure on Sjælland, and now similar structures across Denmark are being investigated with respect to potential CO2 storage. | Onshore Denmark, natural gas has been successfully and safely stored for around 30 years in the Stenlille structure on Sjælland, and now similar structures across Denmark are being investigated with respect to potential CO2 storage. | ||
| Due to years of hydrocarbon exploitation, | Due to years of hydrocarbon exploitation, | ||
| + | |||
| + | ---- | ||
| + | |||
| + | **The Stenlille Structure** | ||
| On the Stenlille structure, the Upper Triassic sandstone dominated Gassum Formation is the primary reservoir for natural gas storage. The uppermost Triassic to Lower Jurassic Fjerritslev Formation (mudstone) is the primary seal. The Lower Cretaceous Vedsted and Rødby Formations comprise the secondary seal and are often below seismic resolution. | On the Stenlille structure, the Upper Triassic sandstone dominated Gassum Formation is the primary reservoir for natural gas storage. The uppermost Triassic to Lower Jurassic Fjerritslev Formation (mudstone) is the primary seal. The Lower Cretaceous Vedsted and Rødby Formations comprise the secondary seal and are often below seismic resolution. | ||
| Line 22: | Line 30: | ||
| //The Stenlille storage complex showing primary and secondary reservoirs and seals.// | //The Stenlille storage complex showing primary and secondary reservoirs and seals.// | ||
| - | |||
| - | Using core, sidewall core and ditch cuttings samples from the Gassum and Fjerritslev formations from 20 wells over the Stenlille structure, Lindström et al. (in review) have established a new high-resolution biostratigraphic zonation for the reservoir and primary seal using spores, pollen and dinoflagellate cysts which is integrated with the sequence stratigraphic framework and will be an important tool for dating future wells in other potential gas storage sites (see Gregersen et al. 2023 [[https:// | ||
| ---- | ---- | ||
| + | |||
| + | **Palynological Biostratigrahy of the Reservoir of the Stenlille Structure** | ||
| + | |||
| + | Using core, sidewall core and ditch cuttings samples from the Gassum and Fjerritslev formations from 20 wells over the Stenlille structure, Lindström et al. (in review) have established a new high-resolution biostratigraphic zonation for the reservoir and primary seal using spores, pollen and dinoflagellate cysts which is integrated with the sequence stratigraphic framework and will be an important tool for dating future wells in other potential gas storage sites (see Gregersen et al. 2023 [[https:// | ||
| {{: | {{: | ||
| - | // | + | // |
| {{: | {{: | ||
| Line 36: | Line 46: | ||
| ---- | ---- | ||
| + | |||
| + | **Stenlille Lower Cretaceous (Seal) Thicknesses** | ||
| Previous biostratigraphic studies on the Cretaceous succession were carried out 70-90 years ago were based on foraminifera and ostracods, mostly from ditch cuttings samples. Recently core and ditch cuttings samples from the Lower Cretaceous Vedsted and Rødby Formations (secondary seal) of several Stenlille wells were examined for the first time for their calcareous nannofossil content. The nannofossil biostratigraphy is based on the zonation of Bown et al. (1998), which for years has been successfully applied to Lower Cretaceous chalks and marls in the North Sea. The new study has resulted in a revised biostratigraphy for the Lower Cretaceous succession, constrained the age of the secondary seal and has shown that its thickness is significantly reduced compared with thicknesses estimated by seismic surveys and vintage biostratigraphic studies (Gregersen et al. 2023). | Previous biostratigraphic studies on the Cretaceous succession were carried out 70-90 years ago were based on foraminifera and ostracods, mostly from ditch cuttings samples. Recently core and ditch cuttings samples from the Lower Cretaceous Vedsted and Rødby Formations (secondary seal) of several Stenlille wells were examined for the first time for their calcareous nannofossil content. The nannofossil biostratigraphy is based on the zonation of Bown et al. (1998), which for years has been successfully applied to Lower Cretaceous chalks and marls in the North Sea. The new study has resulted in a revised biostratigraphy for the Lower Cretaceous succession, constrained the age of the secondary seal and has shown that its thickness is significantly reduced compared with thicknesses estimated by seismic surveys and vintage biostratigraphic studies (Gregersen et al. 2023). | ||
et_stenille.1687168408.txt.gz · Last modified: 19/06/2023 09:53 by mike_gss