Skip to Main Content
Skip Nav Destination

Effects of hydrocarbon generation, basal heat flow and sediment compaction on overpressure development: a numerical study

Petroleum Geoscience (2005) 11 (4): 353–360.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
East European sedimentary basins long heated by a fading mantle upwelling
Nature Communications (2024) 15 (1)
An innovative approach for investigation of overpressure due to hydrocarbon generation: a regional study on Kazhdumi formation, South-western Zagros Basin, Iran
Journal of Petroleum Exploration and Production Technology (2024)
Hydrogen's organic genesis
Unconventional Resources (2024) 4: 100057.
A multi-proxy approach to detect the pore pressure and the origin of overpressure in sedimentary basins: An example from the Gulf of Suez rift basin
Frontiers in Earth Science (2022) 10
The Rise, Peak and Decline of the Seismic Hazard Related to Hydraulic Fracturing Activities in the Duvernay Play, Fox Creek Area, Alberta
Journal of Geophysical Research: Solid Earth (2022) 127 (1)
3D seismic classification of fluid escape pipes in the western Exmouth Plateau, North West Shelf of Australia
Journal of the Geological Society (2021) 178 (3)
Sedimentary-Condensation Model of Formation of Hydrocarbon Fields in the South Caspian Basin
Izvestiya, Atmospheric and Oceanic Physics (2021) 57 (10): 1349.
Using seismic and well data to determine processes of folding in the Pomeranian segment of the Caledonian Foredeep Basin, Poland
Marine and Petroleum Geology (2021) 124: 104804.
Impact of tectonic shortening on fluid overpressure in petroleum system modelling: Insights from the Neuquén basin, Argentina
Marine and Petroleum Geology (2021) 127: 104933.
Shale transformations and physical properties—Implications for seismic expression of mobile shales
Earth-Science Reviews (2021) 220: 103746.
Overpressure generation and evolution in Lower Paleozoic gas shales of the Jiaoshiba region, China: Implications for shale gas accumulation
Marine and Petroleum Geology (2019) 102: 844.
Factors controlling reservoir properties and hydrocarbon accumulation of the Eocene lacustrine beach-bar sandstones in the Dongying Depression, Bohai Bay Basin, China
Marine and Petroleum Geology (2019) 99: 1.
Hydrocarbon downward accumulation from an upper oil source to the oil reservoir below in an extensional basin: A case study of Chezhen Depression in the Bohai Bay Basin
Marine and Petroleum Geology (2019) 103: 516.
Main Mechanism for Generating Overpressure in the Paleogene Source Rock Series of the Chezhen Depression, Bohai Bay Basin, China
Journal of Earth Science (2019) 30 (4): 775.
Increased likelihood of induced seismicity in highly overpressured shale formations
Geophysical Journal International (2018) 214 (1): 751.
Advective Heat Transport and the Salt Chimney Effect: A Numerical Analysis
Geofluids (2018) 2018: 1.
Natural Fractures Characterization and In Situ Stresses Inference in a Carbonate Reservoir—An Integrated Approach
Energies (2018) 11 (2): 312.
Diagenesis and hydrocarbon emplacement in the Upper Triassic Yanchang Formation tight sandstones in the southern Ordos Basin, China
Australian Journal of Earth Sciences (2017) 64 (7): 957.
Geothermometry and geobarometry of overpressured lower Paleozoic gas shales in the Jiaoshiba field, Central China: Insight from fluid inclusions in fracture cements
Marine and Petroleum Geology (2017) 83: 124.
Geochemistry of formation waters from the Wolfcamp and “Cline” shales: Insights into brine origin, reservoir connectivity, and fluid flow in the Permian Basin, USA
Chemical Geology (2016) 425: 76.
Controls on structural styles along the deformation front of the Subandean zone of southern Bolivia
Journal of Structural Geology (2015) 73: 83.
A Novel Energy-Efficient Pyrolysis Process: Self-pyrolysis of Oil Shale Triggered by Topochemical Heat in a Horizontal Fixed Bed
Scientific Reports (2015) 5 (1)
A disequilibrium compaction model constrained by seismic data and application to overpressure generation in The Eastern Black Sea Basin
Basin Research (2013) 25 (3): 331.
The role of pressure in thermocatalytic processes in the sedimentary complex of the South Caspian basin
Russian Geology and Geophysics (2013) 54 (2): 200.
Hydrocarbon migration in the Zagros Basin, offshore Iran, for understanding the fluid flow in the Oligocene–Miocene carbonate reservoirs
Russian Geology and Geophysics (2013) 54 (1): 64.
Inverse modelling and seismic data constraints on overpressure generation by disequilibrium compaction and aquathermal pressuring: application to the Eastern Black Sea Basin
Geophysical Journal International (2013) 194 (2): 814.
Paleofluid analysis from fracture-fill cements in the Asmari limestones of the Kuh-I-Mond field, SW Zagros, Iran
Arabian Journal of Geosciences (2013) 6 (7): 2539.
2-D Basin modeling study of petroleum systems in the Levantine Basin, Eastern Mediterranean
GeoArabia (2011) 16 (2): 17.
Organic Matter Maturity and Clay Mineral Transformations in Overpressured Formations: Comparison Histories from Two Zones of the South Caspian Basin
Energy Exploration & Exploitation (2011) 29 (1): 21.
Distribution and mechanisms of overpressure generation and deflation in the late Neoproterozoic to early Cambrian South Oman Salt Basin
Geofluids (2011) 11 (4): 349.
Effects of hydrocarbon generation on fluid flow in the Ordos Basin and its relationship to uranium mineralization
Geoscience Frontiers (2011) 2 (3): 439.
Downward hydrocarbon migration predicted from numerical modeling of fluid overpressure in the Paleozoic Anticosti Basin, eastern Canada
Geofluids (2010) 10 (3): 334.
Role of effective permeability distribution in estimating overpressure using basin modelling
Marine and Petroleum Geology (2010) 27 (8): 1684.
Co-current combustion of oil shale – Part 2: Structure of the combustion front
Fuel (2010) 89 (1): 133.
Wide-angle seismic data reveal extensive overpressures in the Eastern Black Sea Basin
Geophysical Journal International (2009) 178 (2): 1145.
Occurrence and Nature of Overpressure in the Sedimentary Section of the South Caspian Basin, Azerbaijan
Energy Exploration & Exploitation (2009) 27 (5): 345.
A numerical model for coupled fluid flow and matrix deformation with applications to disequilibrium compaction and delta stability
Journal of Geophysical Research: Solid Earth (2007) 112 (B10)
Factors controlling the thermo-mechanical deformation of oil shales: Implications for compaction of mudstones and exploitation
Marine and Petroleum Geology (2006) 23 (7): 715.
Close Modal

or Create an Account

Close Modal
Close Modal