- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
NARROW
GeoRef Subject
-
all geography including DSDP/ODP Sites and Legs
-
Asia
-
Far East
-
China
-
Bohaiwan Basin (1)
-
Ordos Basin (3)
-
Qaidam Basin (1)
-
Sichuan Basin (1)
-
Songliao Basin (1)
-
Xinjiang China
-
Junggar Basin (1)
-
Tahe Field (1)
-
Tarim Basin (2)
-
-
-
-
-
Atlantic Ocean
-
North Atlantic
-
English Channel (1)
-
Faeroe-Shetland Basin (1)
-
Irish Sea (6)
-
North Sea
-
East Shetland Basin (2)
-
-
-
-
Central Graben (1)
-
Europe
-
Western Europe
-
Netherlands (1)
-
United Kingdom
-
Great Britain
-
England
-
Cheshire England (3)
-
Cumbria England
-
Sellafield England (1)
-
-
Lancashire England (2)
-
Morecambe Bay (1)
-
Pennines (1)
-
Shropshire England (1)
-
Staffordshire England (1)
-
Wessex Basin (1)
-
West Midlands (1)
-
-
Scotland
-
Glasgow Scotland (1)
-
Moray Firth (1)
-
-
Wales (4)
-
-
-
-
-
Lake District (1)
-
Liverpool Bay (3)
-
Mersey Valley (1)
-
United States
-
Anadarko Basin (1)
-
Oklahoma
-
Caddo County Oklahoma (1)
-
-
-
-
commodities
-
energy sources (1)
-
geothermal energy (1)
-
metal ores
-
iron ores (1)
-
-
mineral deposits, genesis (3)
-
mineral resources (1)
-
nonmetal deposits (1)
-
oil and gas fields (9)
-
petroleum
-
natural gas
-
shale gas (2)
-
-
-
tight sands (2)
-
water resources (1)
-
-
elements, isotopes
-
carbon
-
C-13/C-12 (1)
-
-
isotope ratios (1)
-
isotopes
-
stable isotopes
-
C-13/C-12 (1)
-
S-34/S-32 (1)
-
-
-
metals
-
alkaline earth metals
-
calcium (1)
-
-
iron (1)
-
-
sulfur
-
S-34/S-32 (1)
-
-
-
fossils
-
microfossils (2)
-
palynomorphs
-
miospores
-
pollen (1)
-
-
-
-
geologic age
-
Coal Measures (1)
-
Mesozoic
-
Jurassic
-
Lower Jurassic (1)
-
Middle Jurassic (1)
-
-
Triassic
-
Lower Triassic (1)
-
Sherwood Sandstone (4)
-
Upper Triassic
-
Mercia Mudstone (4)
-
Rhaetian
-
Penarth Group (1)
-
-
-
-
-
Paleozoic
-
Carboniferous
-
Lower Carboniferous (2)
-
Middle Carboniferous (1)
-
Mississippian (1)
-
Pennsylvanian
-
Upper Pennsylvanian (1)
-
-
Upper Carboniferous
-
Stephanian (1)
-
Westphalian (1)
-
-
-
Ordovician (1)
-
Permian
-
Shihezi Formation (1)
-
Upper Permian (1)
-
-
Silurian (1)
-
upper Paleozoic
-
Shanxi Formation (1)
-
-
-
-
igneous rocks
-
igneous rocks
-
plutonic rocks
-
granites (1)
-
-
-
-
minerals
-
carbonates
-
calcite (1)
-
siderite (1)
-
-
silicates
-
sheet silicates (1)
-
-
-
Primary terms
-
Asia
-
Far East
-
China
-
Bohaiwan Basin (1)
-
Ordos Basin (3)
-
Qaidam Basin (1)
-
Sichuan Basin (1)
-
Songliao Basin (1)
-
Xinjiang China
-
Junggar Basin (1)
-
Tahe Field (1)
-
Tarim Basin (2)
-
-
-
-
-
Atlantic Ocean
-
North Atlantic
-
English Channel (1)
-
Faeroe-Shetland Basin (1)
-
Irish Sea (6)
-
North Sea
-
East Shetland Basin (2)
-
-
-
-
carbon
-
C-13/C-12 (1)
-
-
continental shelf (1)
-
crust (1)
-
deformation (3)
-
diagenesis (7)
-
economic geology (2)
-
energy sources (1)
-
Europe
-
Western Europe
-
Netherlands (1)
-
United Kingdom
-
Great Britain
-
England
-
Cheshire England (3)
-
Cumbria England
-
Sellafield England (1)
-
-
Lancashire England (2)
-
Morecambe Bay (1)
-
Pennines (1)
-
Shropshire England (1)
-
Staffordshire England (1)
-
Wessex Basin (1)
-
West Midlands (1)
-
-
Scotland
-
Glasgow Scotland (1)
-
Moray Firth (1)
-
-
Wales (4)
-
-
-
-
-
faults (10)
-
folds (2)
-
geology (1)
-
geophysical methods (9)
-
geophysics (1)
-
geothermal energy (1)
-
ground water (3)
-
hydrology (1)
-
igneous rocks
-
plutonic rocks
-
granites (1)
-
-
-
inclusions
-
fluid inclusions (4)
-
-
isotopes
-
stable isotopes
-
C-13/C-12 (1)
-
S-34/S-32 (1)
-
-
-
Mesozoic
-
Jurassic
-
Lower Jurassic (1)
-
Middle Jurassic (1)
-
-
Triassic
-
Lower Triassic (1)
-
Sherwood Sandstone (4)
-
Upper Triassic
-
Mercia Mudstone (4)
-
Rhaetian
-
Penarth Group (1)
-
-
-
-
-
metal ores
-
iron ores (1)
-
-
metals
-
alkaline earth metals
-
calcium (1)
-
-
iron (1)
-
-
metasomatism (1)
-
mineral deposits, genesis (3)
-
mineral resources (1)
-
nonmetal deposits (1)
-
oil and gas fields (9)
-
orogeny (2)
-
Paleozoic
-
Carboniferous
-
Lower Carboniferous (2)
-
Middle Carboniferous (1)
-
Mississippian (1)
-
Pennsylvanian
-
Upper Pennsylvanian (1)
-
-
Upper Carboniferous
-
Stephanian (1)
-
Westphalian (1)
-
-
-
Ordovician (1)
-
Permian
-
Shihezi Formation (1)
-
Upper Permian (1)
-
-
Silurian (1)
-
upper Paleozoic
-
Shanxi Formation (1)
-
-
-
palynomorphs
-
miospores
-
pollen (1)
-
-
-
petroleum
-
natural gas
-
shale gas (2)
-
-
-
pollution (1)
-
sedimentary rocks
-
carbonate rocks (1)
-
clastic rocks
-
arenite
-
quartz arenite (1)
-
-
conglomerate (1)
-
red beds (2)
-
sandstone (10)
-
shale (2)
-
subarkose (1)
-
-
-
stratigraphy (3)
-
sulfur
-
S-34/S-32 (1)
-
-
tectonics (4)
-
thermal waters (1)
-
United States
-
Anadarko Basin (1)
-
Oklahoma
-
Caddo County Oklahoma (1)
-
-
-
water resources (1)
-
-
sedimentary rocks
-
sedimentary rocks
-
carbonate rocks (1)
-
clastic rocks
-
arenite
-
quartz arenite (1)
-
-
conglomerate (1)
-
red beds (2)
-
sandstone (10)
-
shale (2)
-
subarkose (1)
-
-
-
Collyhurst Sandstone Formation
A sensitivity analysis of a single extraction well from deep geothermal aquifers in the Cheshire Basin, UK
The Elswick Field, Bowland Basin, UK Onshore
Abstract The Elswick Field is located within Exploration Licence EXL 269a (Cuadrilla Resources Ltd is the operator) on the Fylde peninsula, West Lancashire, UK. It is the first producing onshore gas field to be developed by hydraulic fracture stimulation in the region. Production from the single well field started in 1996 and has produced over 0.5 bcf for onsite electricity generation. Geologically, the field lies within a Tertiary domal structure within the Elswick Graben, Bowland Basin. The reservoir is the Permian Collyhurst Sandstone Formation: tight, low-porosity fluvial desert sandstones, alluvial fan conglomerates and argillaceous sandstones. The reservoir quality is primarily controlled by depositional processes further reduced by diagenesis. Depth to the reservoir is 3331 ft TVDSS with the gas–water contact at 3400 ft TVDSS and with a net pay thickness of 38 ft.
Correlation of seismic to well ties for the Grange Hill-1Z, Preese Hall-1 a...
The Permian to Jurassic stratigraphy and structural evolution of the central Cheshire Basin
Discussion on the Permian to Jurassic stratigraphy and structural evolution of the central Cheshire Basin
Discussion on genetic studies of red bed mineralization in the Triassic of the Cheshire Basin, northwest England
Structural constraints on Lower Carboniferous shale gas exploration in the Craven Basin, NW England
Abstract The Hamilton and Hamilton North Fields are located in Block 110/13a in the East Irish Sea, and contain 627 BCF and 230 BCF GIIP, respectively. First gas was produced from the Hamilton North Field in December 1995. The fields are being developed with four producers in the Hamilton Field and three in the Hamilton North Field. The Hamilton Field structure consists of a N-S trending horst block with dip closure to the north and south, while the Hamilton North structure is defined by major faults to the north and west with dip closure to the east and south. The gas is trapped in the highly productive Triassic Ormskirk Sandstone Formation. The reservoir comprises high porosity aeolian and fluvial sandstones. Depth to reservoir is shallow (2300-2600 ft) with the gas-water contact being at 2910ft in the Hamilton Field and 3166 ft in the Hamilton North Field. Reservoir quality is principally controlled by primary depositional processes and no significant diagenetic effects are observed. The hydrocarbon filling history was complex, with at least two phases of hydrocarbon generation. Hamilton North gas is sweet whereas the Hamilton gas contains up to 1100ppm H 2 S, which is removed during processing at the Douglas complex and at the Point of Ayr gas terminal. Cumulative gas production to May 1999 was 180 BCF and no water-cut has been observed to date.
Abstract The Lennox Field, located in blocks 110/15 and 110/14, was the second oil field to be developed in the East Irish Sea Basin. It contains 184 MMBBL of oil in-place within a 143 ft thick oil rim overlain by a large gas cap up to 750 ft thick. The GIIP is estimated to be 497 BCF. The field came on stream in February 1996, and it is now being developed with seven horizontal oil producers, including two multi-lateral wells and two crestal gas injectors. Production from the field can be divided into two distinct phases; the oil rim development phase, and the gas cap blow-down phase. The latter phase is currently anticipated to commence in 2004. The field structure consists of a roll-over anticline formed in the hanging wall of the Formby Point Fault during extensional faulting in Triassic-early Jurassic times, and later readjusted by contractional movements during Tertiary inversion. The oil and gas are trapped in the highly productive Triassic Ormskirk Sandstone Formation. The reservoir comprise high porosity aeolian and fluvial sandstones occurring at a shallow depth (c. 2500 ft) with a maximum gas column of 750 ft above an oil rim of 143 ft. The reservoir quality is principally controlled by primary depositional processes as no significant adverse diagenetic effects are observed. The hydrocarbon filling history was complex, with at least three phases of oil and gas generation. The field contains a light, saturated oil (45° API) with a GOR of 650 SCF/BBL. The crude contains high levels of H 2 S (0.1 mol%) and mercaptans (450 ppm), which are removed during processing at the Douglas complex. Water cut from the field is currently around 2-5%, and no free gas production has been observed to date. Gas production from Lennox is anticipated to start in 2004.
The critical evaluation of carbon dioxide subsurface storage sites: Geological challenges in the depleted fields of Liverpool Bay
Hydrocarbon potential of the Kish Bank Basin: Integration within a regional model for the Greater Irish Sea Basin
Abstract The Kish Bank Basin lies in the western Irish Sea c. 20 km east of Dublin. It is one of a number of remnants of a larger Permo-Triassic basin system that may have extended across the whole of the Irish Sea. It has a geological history similar to that of the East Irish Sea Basin, initially developing by the reactivation of Caledonian faults that controlled subsequent deposition during Dinantian and Namurian time, with Westphalian deposition in a sag-basin that overstepped the adjacent basement highs. Variscan dextral transpression resulted in the formation of the Codling and Bray faults, and Permian to Jurassic extension formed a set of north-south-trending faults. Liassic outliers are preserved in the hanging walls of the basin margin faults. Early Cretaceous uplift was followed by chalk deposition. Tertiary movements reactivated older faults, isolating the Kish Bank Basin, and producing 9 km of dextral strike-slip along the Codling Fault Zone. The main reservoir in the hydrocarbon play is provided by the Sherwood Sandstone Group, as successfully exploited in the East Irish Sea. Three wells have been drilled to test this reservoir. These encountered high-quality Sherwood Sandstone reservoirs beneath the good potential seal of the Mercia Mudstone Group (which included thick halites). Source rock potential is from either the Westphalian Coal Measures, as penetrated in well 33/22-1, or from inferred Dinantian to Namurian basinal shales. There is good evidence of an active source system, with oil shows in wells 33/17-1 and 33/22-1, data from geochemical analysis of sea-bed cores, a ‘Seepfinder’ survey, sea-bed mounds and seismic evidence of shallow gas. The main risks of the play are the migration pathway and the timing of trap formation with respect to migration. Migration favours the eastern side of the basin, and many of the tilted fault blocks that formed during Permian to Jurassic time have been modified by Early Cretaceous inversion and by Tertiary strike-slip compression. ALL of the structures that have been drilled to date have been either formed or modified after the time of peak hydrocarbon generation and migration.
Abstract The Douglas Field is located in Block 110/13b in the East Irish Sea. It was the first oilfield to be discovered and produced in the region, having been found in 1990 and brought on stream in January 1996. The field structure comprises a series of north–south-trending, tilted, extensional fault blocks. The reservoir interval is the Triassic Ormskirk Sandstone Formation comprising good quality aeolian and fluvial sandstones. The field is relatively shallow, with the top reservoir at c. 2120 ft true vertical depth subsea. The hydrocarbon is a light oil of 44°API gravity with a maximum column height of c. 400 ft. The Douglas Field contains an estimated stock tank oil in place of 248 MMbbl and was developed with 22 wells: 15 producers, six water injectors and a single sour gas and condensate disposal well. Electric submersible pumps are installed in oil producers for artificial lift and water injection was utilized from field start-up for pressure maintenance. A water-alternating-gas pilot was implemented on the field in 2017 as an enhanced oil recovery scheme. The field currently produces at a rate of c. 4000 bopd, with approximately 90% water cut. The field has produced 103 MMbbl to date, giving a current oil recovery of c. 41%.
Applied geological mapping for planning and development: an example from Wigan, UK
The history of exploration and development of the Liverpool Bay fields and the East Irish Sea Basin
Abstract Hydrocarbon exploration in the East Irish Sea Basin began with the identification of surface oil seeps in peat beds in Lancashire, UK. This precipitated the drilling of the first onshore exploration wells. The discovery of the Formby Field in west Lancashire at the end of the 1930s triggered a wave of further drilling. Wells drilled in west Lancashire had limited success, with only minor hydrocarbon shows, whilst the production from the Formby Field was modest. Nonetheless, the invaluable geological information taken from onshore wells and the ratification of the Continental Shelf Act led to a shift in focus to the offshore and a period of significant interest in the East Irish Sea. Two key periods of oil and gas exploration activity stand out in the history of the offshore basin, the first headed by the Gas Council during the 1970s resulted in the discovery of the gas giants of Morecambe Bay, whilst the second fronted by Hamilton Oil during the 1990s heralded the discovery of oil with the Douglas and Lennox fields in Liverpool Bay. Exploration in the basin has waned during the last decade; however, to date, this mature hydrocarbon province has yielded estimated hydrocarbon reserves of over 1.8 BBOE (billion barrels of oil equivalent).
Formation Time and Material Source of Carbonate Cements in Permian Sandstone in the Ordos Basin, Western of China
Shale gas resources of the Bowland Basin, NW England: a holistic study
Diagenetic alteration, pore-throat network, and reservoir quality of tight gas sandstone reservoirs: A case study of the upper Paleozoic sequence in the northern Tianhuan depression in the Ordos Basin, China
Abstract The Douglas Field, on stream in February 1996, is the first oil field to be developed in the East Irish Sea Basin, with an estimated STOIIP of 202 MMBBL. The field structure consists of three tilted fault blocks formed during extensional faulting in Triassic-early Jurassic times, and later readjusted by contractional movements during Tertiary inversion. The oil is trapped in the Triassic Ormskirk Sandstone Formation, which comprises moderate to high porosity aeolian and fluvial sandstones. The reservoir depth is shallow (2140 ft) with a maximum oil column of 375 ft. The reservoir can be divided into several laterally extensive units based on vertical facies variations. The reservoir quality is principally controlled by primary depositional processes, and authigenic clay minerals are not important. However, bitumen is formed extensively in specific areas of the field causing significant permeability reduction. The hydrocarbon filling history of the field was complex, with the occurrence of at least two phases of oil generation and migration. The field contains a relatively ‘dead’ oil with a low GOR (170 scf/bbl). Pressure maintenance is achieved through sea water injection, and to date ten production and six injection wells have been drilled. The crude is light (44° API) and contains high levels of H 2 S (0.5mol%) and mercaptans, which are removed during processing offshore.
Integration of diagenesis, porosity evolution, and oil emplacement in lacustrine tight sandstone reservoirs: A review with illustrative cases from the major oil-bearing basins in China
Permian: arid basins and hypersaline seas
Abstract The distribution of Permian rocks in England and Wales ( Fig. 12.1 ) is more complex than that of the overlying Mesozoic formations, which in the onshore area form a broad swathe displaying, as William Smith noted, an overall NE–SW-trending strike. Permian sediments, by contrast, are more patchily developed but rest in many locations on Carboniferous rocks, with a palaeotopography generated by Variscan mountain building and later erosion. Assessment of how the Permian landscape might have appeared is best achieved through consideration of the sedimentary evidence from both the Permian and the preceding Carboniferous strata. There are strong indications in the rock record of a changing tectonic and palaeoclimatic regime in NW Europe during this time, which reflected broader, even global, events. The general tectonic scene was one in which the southern supercontinent Gondwana moved north through Carboniferous time to collide with its northern counterpart Laurasia in the latest Carboniferous and earliest Permian. This continental collision was achieved as the Devonian–Carboniferous Rheic Ocean closed and Pangaea formed ( Fig. 12.2 ). Simultaneously, the Ural Mountains were forming as the Kazakstan microplate collided with Fennos- candia, the final coalescence of Pangaea. The sedimentary fill of the Rheic Ocean is now preserved as deformed and locally metamorphosed pre-Permian successions in Cornwall, Devon, northern France,Belgium and Germany.