Basin inversion controls on diagenetic evolution of Lower Cretaceous non-marine succession: the English Wealden sandstones

doi:10.1016/j.jop.2024.12.003

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Abstract

Modelling the diagenetic history of a tectonically active basin is crucial for understanding the depositional and post-depositional processes including the evolution and development of porosity and permeability. This study describes the diagenetic imprints of the inverted Lower Cretaceous Weald Basin and examines the depositional and tectonic controls on the diagenetic, porosity and permeability evolution of its sandstones. Seventy-two representative sandstone samples from the Weald Basin were subjected to detailed microscopic (optical and scanning electron) analyses. The dominant early diagenetic fabrics include grain-coating detrital clays, degraded and dissolved detrital grains, and vermiform kaolinite pore-filling cement while uplift-related or telogenetic characteristics are mainly post-compactional pore-filling goethite and hematite cement. This work is significant because it presents the first diagenetic model of the Lower Cretaceous Wealden sandstones which can be very useful for understanding basins with similar depositional and tectonic settings.

Key words： Diagenesis Diagenetic evolution Basin inversion Lower Cretaceous English

Received: 22 January 2024

Corresponding Authors: ^*Anglia Ruskin University, Bishop Hall Lane, Chelmsford, CM1 1SQ, United Kingdom.E-mail address: oladapo.akinlotan@aru.ac.uk (O.O. Akinlotan).Peer review under responsibility of China University of Petroleum (Beijing).

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http://journal09.magtechjournal.com/Jweb_jop/EN/10.1016/j.jop.2024.12.003 OR http://journal09.magtechjournal.com/Jweb_jop/EN/Y2025/V14/I1/15

Adamovič J.,2005. Sandstone cementation and its geomorphic and hydraulic implications.Ferrantia, 44, 21-24.
Ajdukiewicz J. M., Lander R. H., 2010. Sandstone reservoir quality prediction: The state of the art.AAPG Bulletin, 94(8), 1083-1091.
Akinlotan O. O.,2015. The Sedimentology of the Ashdown Formation and the Wadhurst Clay Formation, Southeast England. [PhD thesis]. University of Brighton. United Kingdom.
Akinlotan O. O.,2016. Porosity and permeability of the English (Lower Cretaceous) sandstones.Proceedings of the Geologists' Association, 127(6), 681-690.
Akinlotan O. O.,2017a. Geochemical analysis for palaeoenvironmental interpretations - a case study of the English Wealden (Lower Cretaceous, southeast England). Geological Quarterly, 61(1), 227-238. https://gq.pgi.gov.pl/article/view/25482.
Akinlotan O. O.,2017b. Mineralogy and palaeoenvironments: the Weald Basin (Early Cretaceous), Southeast England. The Depositional Record, 3(2), 187-200. https://doi.org/10.1002/dep2.32.
Akinlotan O. O.,2018. Multi-proxy approach to palaeoenvironmental modelling: the English Lower Cretaceous Weald Basin. Geological Journal, 53, 316-335. https://gq.pgi.gov.pl/article/view/25482.
Akinlotan O. O.,2019. Sideritic ironstones as indicators of depositional environments in the Weald Basin (Early Cretaceous) SE England. Geological Magazine, 156(3), 533-546. https://doi.org/10.1017/S0016756817001017.
Akinlotan O. O., Adepehin E. J., Rogers G. H., Drumm E. C.,2021. Provenance, palaeoclimate and palaeoenvironments of a non-marine Lower Cretaceous facies: Petrographic evidence from the Wealden Succession. Sedimentary Geology, 415, 105848. https://doi.org/10.1016/j.sedgeo.2020.105848.
Akinlotan O. O., Hatter S. J., 2022. Depositional controls on diagenetic evolution of the Lower Cretaceous Wealden Sandstones (Wessex Basin, southeast England).Marine and Petroleum Geology, 146, 105948.
Akinlotan O. O., Moghalu O. A., Hatter S. J., Okunuwadje S. E., Anquilano L., Onwukwe U., Haghani S., Anyiam O. A., Jolly B. A., 2022. Clay mineral formation and transformation in non-marine environments and implications for Early Cretaceous palaeoclimatic evolution: the Weald Basin, southeast England.Journal of Palaeogeography, 11(3) 387-409
Akinlotan O. O., Rogers G. H.,2021. Heavy mineral constraints on the provenance evolution of the English Lower Cretaceous (Wessex Basin). Marine and Petroleum Geology, 104952. https://doi.org/10.1016/j.marpetgeo.2021.104952.
Allard J. O., Foix N., Bueti S. A., Sánchez F. M., Ferreira M. L., Atencio M.,2020. Comparative structural analysis of inverted structures in the San Bernardo fold belt (Golfo San Jorge basin, Argentina): Inversion controls and tecto-sedimentary context of the Chubut Group. Journal of South American Earth Sciences, 97, 102405. https://doi.org/10.1016/j.jsames.2019.102405.
Allen P.,1975. Wealden of the Weald: a new model. Proceedings of the Geologists' Association, 86(4), 389-437. https://doi.org/10.1016/S0016-7878(75)80057-5.
Allen P.,1981. Pursuit of Wealden models. Journal of the Geological Society, 138(4), 375-405. https://doi.org/10.1144/gsjgs.138.4.0375.
Amir L., Martinez L., Disnar J.-R., Vigneresse J.-L., Michels R., Guillocheau F., Robin C., 2005. Effect of the thermal gradient variation through geological time on basin modeling; a case study: the Paris basin.Tectonophysics, 400(1-4), 227-240.
Angerer T., Hagemann S. G., Walde D. H., 2021. Diagenetic and supergene ore forming processes in the iron formation of the Neoproterozoic Jacadigo Group, Corumbá, Brazil.Journal of South American Earth Sciences, 105, 102902.
Baiyegunhi C., Liu K., Gwavava O., 2017. Diagenesis and reservoir properties of the permian Ecca Group sandstones and mudrocks in the Eastern Cape Province, South Africa.Minerals, 7(6), 88.
Barshep D. V., Worden R. H., 2021. Reservoir quality of Upper Jurassic Corallian Sandstones, Weald Basin, UK.Geosciences, 11(11), 446.
Bjørlykke K.,2014. Relationships between depositional environments, burial history and rock properties. Some principal aspects of diagenetic process in sedimentary basins.Sedimentary Geology, 301, 1-14.
Bjørlykke K., Aagaard P., 1992. Clay minerals in North Sea sandstones. In: D. W. Houseknecht, E. D. Pittman (Eds.), Origin, Diagenesis, and Petrophysics of Clay Minerals in Sandstones . SEPM Special Publication. Vol. 47, pp. 65-80.
Bjørlykke K., Jahren J., 2010. Sandstones and sandstone reservoirs. In: K. Bjørlykke (Ed.), Petroleum Geoscience: Rom Sedimentary Environments to Rock Physics Springer. pp. 113-140.
Bjørlykke K., Ramm M., Saigal G. C., 1989. Sandstone diagenesis and porosity modification during basin evolution.Geologische Rundschau, 78(1), 243-268.
Blaise T., Izart A., Michels R., Suarez-Ruiz I., Cathelineau M., Landrein P., 2011. Vertical and lateral changes in organic matter from the Mesozoic, eastern Paris Basin (France): variability of sources and burial history.International Journal of Coal Geology, 88(2-3), 163-178.
Boggs S. J.,2006. Principles of Sedimentology and Stratigraphy (4 ed.). Pearson Prentice Hall.
Booth K.,2005. Geological investigation of the Ashdown Beds at Fairlight, East Sussex (Commercial Report), Issue. B. G. Survey.
Boyd G., Wallace M., Holdgate G., Gallagher S., 2004. Marine clays and porosity evolution in the Nullawarre Greensand, Otway Basin, southeastern Australia. PESA Eastern Australasian Basins Symposium II Held in Adelaide
Bridgland D. R., Westaway R., Hu Z.,2020. Basin inversion: A worldwide Late Cenozoic phenomenon. Global and Planetary Change, 193, 103260. https://doi.org/10.1016/j.gloplacha.2020.103260.
Brigaud B., Vincent B., Pagel M., Gras A., Noret A., Landrein P., Huret E., 2018. Sedimentary architecture, depositional facies and diagenetic response to intracratonic deformation and climate change inferred from outcrops for a pivotal period (Jurassic/Cretaceous boundary, Paris Basin, France).Sedimentary Geology, 373, 48-76.
Chadwick R. A.,1986. Extension tectonics in the Wessex Basin, southern England. Journal of the Geological Society, 143(3), 465-488. https://doi.org/10.1144/gsjgs.143.3.0465.
Chadwick R. A.,1993. Aspects of basin inversion in southern Britain. Journal of the Geological Society, 150(2), 311-322. https://doi.org/10.1144/gsjgs.150.2.0311.
Chan M., Ormö J., Park A., Stich M., SOUZA‐EGIPSY V., Komatsu G., 2007. Models of iron oxide concretion formation: field, numerical, and laboratory comparisons.Geofluids, 7(3), 356-368.
Clement A. M., Tackett L. S., Ritterbush K. A., Ibarra Y., 2020. Formation and stratigraphic facies distribution of early Jurassic iron oolite deposits from west central Nevada, USA.Sedimentary Geology, 395, 105537.
de Oliveira Jr, J. C., Batista A. H., Cherobim V. F., Favaretto N., 2020. Goethite and hematite in bichromic soil profiles of southern Brazil: Xanthization or yellowing process.CATENA, 188, 104445.
Dinwiddie, L C., Chan M. A., McGinnis R., Myers J. L., Holliday W., 2011. Chronicles of vadose zone diagenesis: cone‐shaped iron oxide concretions, Triassic Trujillo Formation, Palo Duro Canyon, Texas.Geofluids, 11(1), 87-96.
Ehrenberg S.,1993. Preservation of anomalously high porosity in deeply buried sandstones by grain-coating chlorite: examples from the Norwegian continental shelf.AAPG Bulletin, 77(7), 1260-1286.
Ehrenberg S. N., Nadeau P. H., Steen Ø., 2008. A megascale view of reservoir quality in producing sandstones from the offshore Gulf of Mexico.AAPG Bulletin, 92(2), 145-164.
Er C., Li Y., Zhao J., Wang R., Bai Z., Han Q., 2016. Pore formation and occurrence in the organic-rich shales of the Triassic Chang-7 Member, Yanchang Formation, Ordos Basin, China.Journal of Natural Gas Geoscience, 1(6), 435-444.
Fischer C., Dunkl I., Von Eynatten H., Wijbrans J. R., Gaupp R., 2012. Products and timing of diagenetic processes in Upper Rotliegend sandstones from Bebertal (North German Basin, Parchim Formation, Flechtingen High, Germany). Geological Magazine, 149(5), 827-840. https://doi.org/10.1017/S0016756811001087.
Garcia-Frank A., Ureta S., Mas R., 2012. Iron-coated particles from condensed Aalenian-Bajocian deposits: evolutionary model (Iberian Basin, Spain).Journal of Sedimentary Research, 82(12), 953-968.
Gualtieri A. F., Venturelli P., 1999. In situ study of the goethite-hematite phase transformation by real time synchrotron powder diffraction.American Mineralogist, 84(5-6), 895-904.
Hansen D. L., Blundell D. J., Nielsen S. B., 2002. A model for the evolution of the Weald Basin.Bulletin of Geological Society of Denmark, 49, 109-118.
Harrison B., Taylor D., Tingate P., Sandiford M., 2012. Heat flow modelling and thermal history of the onshore Gippsland Basin: upside potential for unconventional gas and geothermal resources.
Hopson P., Wilkinson I., Woods M., 2008. A stratigraphical framework for the Lower Cretaceous of England [Research Report](RR /08/03).
James W., Wilmar G. C., Davidson B. G., 1986. Role of quartz type and grain size in silica diagenesis, Nugget Sandstone, south-central Wyoming.Journal of Sedimentary Research, 56(5), 657-662.
Jeans C. V.,2006. Clay mineralogy of the Cretaceous strata of the British Isles.Clay Minerals, 41, 47-150.
Juerges A., Hollis C. E., Marshall J., Crowley S., 2016. The control of basin evolution on patterns of sedimentation and diagenesis: an example from the Mississippian Great Orme, North Wales. Journal of the Geological Society, 173(3), 438. https://doi.org/10.1144/jgs2014-149.
Ketzer J. M., Holz M., Morad S., Al‐Aasm I., 2003. Sequence stratigraphic distribution of diagenetic alterations in coal‐bearing, paralic sandstones: Evidence from the Rio Bonito Formation (early Permian), southern Brazil.Sedimentology, 50(5), 855-877.
Kim H., Park C., Park M.-H., Song Y.,2019. Diagenetic study on the Neogene sedimentary basin as paleoenvironmental proxy data for an offshore CO₂ storage project in Pohang Basin, South Korea. Marine Geology, 416, 105977. https://doi.org/10.1016/j.margeo.2019.105977.
Lai J., Wang G., Ran Y., Zhou Z., 2015. Predictive distribution of high-quality reservoirs of tight gas sandstones by linking diagenesis to depositional facies: Evidence from Xu-2 sandstones in the Penglai area of the central Sichuan basin, China.Journal of Natural Gas Science and Engineering, 23, 97-111.
Lai J., Wang G., Ran Y., Zhou Z., Cui Y., 2016. Impact of diagenesis on the reservoir quality of tight oil sandstones: The case of Upper Triassic Yanchang Formation Chang 7 oil layers in Ordos Basin, China.Journal of Petroleum Science and Engineering, 145, 54-65.
Lake R. D., Shephard-Thorn E. R., 1987. Geology of the Country Around Hastings and Dungeness. HM Stationery Office.
Lake S. D.,1985. The structure and evolution of the Wessex Basin. [PhD thesis], Durham University, United Kingdom. United Kingdom.
Lake S. D., Karner G. D., 1987. The structure and evolution of the Wessex Basin, southern England: an example of inversion tectonics. Tectonophysics, 137(1-4), 347-378. https://doi.org/10.1016/0040-1951(87)90328-3.
Lawson M. J., Roder B. J., Stang D. M., Rhodes E. J., 2012. OSL and IRSL characteristics of quartz and feldspar from southern California, USA.Radiation Measurements, 47(9), 830-836.
Liao W.Z., Lin A. T., Liu C. S., Oung J. N., Wang Y., 2014. Heat flow in the rifted continental margin of the South China Sea near Taiwan and its tectonic implications.Journal of Asian Earth Sciences, 92, 233-244.
Luo L., Meng W., Gluyas J., Tan X., Gao X., Feng M., Kong X., Shao H., 2019. Diagenetic characteristics, evolution, controlling factors of diagenetic system and their impacts on reservoir quality in tight deltaic sandstones: Typical example from the Xujiahe Formation in Western Sichuan Foreland Basin, SW China.Marine and Petroleum Geology, 103, 231-254.
Ma B., Cao Y., Jia Y., 2017. Feldspar dissolution with implications for reservoir quality in tight gas sandstones: Evidence from the Eocene Es4 interval, Dongying Depression, Bohai Bay Basin, China.Journal of Petroleum Science and Engineering, 150, 74-84.
Mansy J. L., Manby G. M., Averbuch O., Everaerts M., Bergerat F., Van Vliet-Lanoe, B., Lamarche, J., Vandycke, S., 2003. Dynamics and inversion of the Mesozoic Basin of the Weald-Boulonnais area: role of basement reactivation. Tectonophysics, 373(1-4), 161-179. https://doi.org/10.1016/S0040-1951(03)00289-0.
McBride E. F.,1989. Quartz cement in sandstones: a review.Earth-Science Reviews, 26(1-3), 69-112.
Miller H. B., Farley K. A., Vasconcelos P. M., Mostert A., Eiler J. M., 2020. Intracrystalline site preference of oxygen isotopes in goethite: A single-mineral paleothermometer.Earth and Planetary Science Letters, 539, 116237.
Morad S., Al-Ramadan K., Ketzer J. M., De Ros L., 2010. The impact of diagenesis on the heterogeneity of sandstone reservoirs: A review of the role of depositional facies and sequence stratigraphy.AAPG Bulletin, 94(8), 1267-1309.
Morad S., Ketzer J., De Ros L. F., 2000. Spatial and temporal distribution of diagenetic alterations in siliciclastic rocks: implications for mass transfer in sedimentary basins.Sedimentology, 47, 95-120.
Mu N., Schulz H.-M., Fu Y., Schovsbo N. H., Wirth R., Rhede D., van Berk W., 2015. Berthierine formation in reservoir rocks from the Siri oilfield (Danish North Sea) as result of fluid-rock interactions: part I. Characterization.Marine and Petroleum Geology, 65, 302-316.
Niegel S., Franz M., 2023. Depositional and diagenetic controls on porosity evolution in sandstone reservoirs of the Stuttgart Formation (North German Basin).Marine and Petroleum Geology, 151, 106157.
Okunuwadje S. E.,2019. Diagenesis, fluids, oil charging and reservoir quality in sandstone reservoirs. [PhD thesis], University of Aberdeen.
Okunuwadje S. E., MacDonald D., Bowden S., 2020. Diagenetic and reservoir quality variation of Miocene sandstone reservoir analogues from three basins of southern California, USA.Journal of Earth Science, 31(5), 930-949.
Oluwadebi A. G., Taylor K. G., Dowey P. J.,2018. Diagenetic controls on the reservoir quality of the tight gas Collyhurst Sandstone Formation, Lower Permian, East Irish Sea Basin, United Kingdom. Sedimentary Geology, 371, 55-74. https://doi.org/10.1016/j.sedgeo.2018.04.006.
Radley J. D., Allen P., 2012. The Wealden (non-marine Lower Cretaceous) of the Weald Sub-basin, southern England. Proceedings of the Geologists' Association, 123(2), 245-318. https://doi.org/10.1016/j.pgeola.2012.01.003.
Rahman M. J. J., Worden R. H., 2016. Diagenesis and its impact on the reservoir quality of Miocene sandstones (Surma Group) from the Bengal Basin, Bangladesh.Marine and Petroleum Geology, 77, 898-915.
Rossi C., Alaminos A., 2014. Evaluating the mechanical compaction of quartzarenites: The importance of sorting (Llanos foreland basin, Colombia).Marine and Petroleum Geology, 56, 222-238.
Saïag J., Brigaud B., Portier É., Desaubliaux G., Bucherie A., Miska S., Pagel M., 2016. Sedimentological control on the diagenesis and reservoir quality of tidal sandstones of the Upper Cape Hay Formation (Permian, Bonaparte Basin, Australia).Marine and Petroleum Geology, 77, 597-624.
Schmid S., Worden R., Fisher Q., 2004. Diagenesis and reservoir quality of the Sherwood Sandstone (Triassic), Corrib field, Slyne basin, west of Ireland.Marine and Petroleum Geology, 21(3), 299-315.
Sheldon H. A., Wheeler J., Worden R. H., Cheadle M. J., 2003. An analysis of the roles of stress, temperature, and pH in chemical compaction of sandstones.Journal of Sedimentary Research, 73(1), 64-71.
Simpson I. R., Gravestock M., Ham D., Leach H., Thompson S. D., 1989. Notes and cross-sections illustrating inversion tectonics in the Wessex Basin. Geological Society, London, Special Publications, 44(1), 123-129. https://doi.org/10.1144/gsl.sp.1989.044.01.08.
Sladen C. P.,1983. Trends in Early Cretaceous clay mineralogy in NW Europe.Zitteliana, 10(349), 57.
Sladen C. P.(1987). Aspects of the clay mineralogy of the Wealden and upper Purbeck rocks. In: R. D. Lake, E. R. Shephard-Thorn. (Eds.), Geology of the Country around Hastings and Dungeness, . HM Stationery Office. pp. 71-72.
Stephenson R., Schiffer C., Peace A., Nielsen S. B., Jess S.,2020. Late Cretaceous-Cenozoic basin inversion and palaeostress fields in the North Atlantic-western Alpine-Tethys realm: Implications for intraplate tectonics. Earth-Science Reviews, 210, 103252. https://doi.org/10.1016/j.earscirev.2020.103252.
Stewart D. J.,1981. A field guide to the Wealden Group of the Hastings area and the Isle of Wight. In: T. Elliott (Ed.), Field guides to modern and ancient fluvial systems in Britain and Spain, International Fluvial Conference. pp. 3.1-3.32.
Stoneley R.,1982. The structural development of the Wessex Basin. Journal of the Geological Society, 139(4), 543-554. https://doi.org/10.1144/gsjgs.139.4.0543.
Suo Y., Li S., Cao X., Wang X., Somerville I., Wang G., Wang P., Liu B.,2020. Mesozoic-Cenozoic basin inversion and geodynamics in East China: A review. Earth-Science Reviews, 210, 103357. https://doi.org/10.1016/j.earscirev.2020.103357.
Taylor K. G.,1990. Berthierine from the non-marine Wealden (Early Cretaceous) sediments of south-east England.Clay Minerals, 25(3), 391-399.
Turner J. P., Williams G. A., 2004. Sedimentary basin inversion and intra-plate shortening.Earth-Science Reviews, 65(3-4), 277-304.
Ulmer-Scholle, D. S., Scholle, P. A., Schieber, J., Raine, R. J., 2014. Diagenesis: iron sulfide, oxide & hydroxide cements. In: D. S. Ulmer-Scholle, P. A. Scholle, J. Schieber, R. J. Raine (Eds.), A Colour Guide to the Petrography of Sandstones, Siltstones, Shales, and Associated Rocks, (). American Petroleum Association of Geologists. Vol. 109, pp. 347-360.
Underhill J. R., Paterson S., 1998. Genesis of tectonic inversion structures: seismic evidence for the development of key structures along the Purbeck-Isle of Wight Disturbance. Journal of the Geological Society, 155(6), 975-992. https://doi.org/10.1144/gsjgs.155.6.0975.
Virolle M., Brigaud B., Beaufort D., Patrier P., Abdelrahman E., Thomas H., Portier E., Samson Y., Bourillot R., Féniès H., 2022. Authigenic berthierine and incipient chloritization in shallowly buried sandstone reservoirs: Key role of the source-to-sink context.GSA Bulletin, 134(3-4), 739-761.
Wilkinson M., Haszeldine R. S., Ellam R. M., Fallick A., 2004. Hydrocarbon filling history from diagenetic evidence: Brent Group, UK North Sea.Marine and Petroleum Geology, 21(4), 443-455.
Wolela A.,2012. Diagenetic evolution and reservoir potential of the Barremian-Cenomanian Debre Libanose Sandstone, Blue Nile (Abay) Basin, Ethiopia. Cretaceous Research, 36, 83-95. https://doi.org/10.1016/j.cretres.2012.02.007.
Worden R., Burley S., 2003. Sandstone diagenesis: the evolution of sand to stone. In: S. Burley, R. H. Worden (Eds.), Sandstone Diagenesis: Recent and Ancient . International Association of Sedimentologists Special Publications. Vol. 4, pp. 1-44.
Worden R., Morad S., 2000. Quartz cementation in oil field sandstones: a review of the key controversies. In: R. H. Worden, S. Morad (Eds.), Quartz Cementation in Sandstones, International Association of Sedimentologists Special Publication. Vol. 29, pp. 1-20.
Worden R. H., Morad S., 2003. Clay minerals in sandstones: controls on formation, distribution and evolution. In: R. H. Worden, S. Morad, (Eds.), Clay Minerals in Sandstones. International Association of Sedimentologists Special Publication, Vol. 34, pp. 1-42.
Worden R. H., Needham S. J., Cuadros J., 2006. The worm gut; a natural clay mineral factory and a possible cause of diagenetic grain coats in sandstones.Journal of Geochemical Exploration, 89(1-3), 428-431.