The geology of the Isle of Wight is dominated by sedimentary rocks of Cretaceous and Paleogene age. This sequence was affected by the late stages of the Alpine Orogeny, forming the Isle of Wight monocline, the cause of the steeply-dipping outcrops of the Chalk Group and overlying Paleogene strata seen at The Needles, Alum Bay and Whitecliff Bay.
Rocks of Devonian, Triassic and Jurassic age are known to be present in the subsurface of the island from boreholes and interpreted seismic reflection profiles. Up to 389 m of presumed Devonian sedimentary rocks been proved by six boreholes drilled on the island, consisting of claystone, siltstone, sandstone and quartzite, similar in type to other dated Devonian sequences. A nearly full Triassic succession has been drilled, reaching a maximum thickness of 450 m. Sandstones of the Sherwood Sandstone Group are overlain by claystones and siltstones of the Mercia Mudstone Group and limestones of the Penarth Group. A complete Jurassic succession is shown by the boreholes at Arreton, reaching over 1400 m in thickness, comprising mainly mudstones of the Lias Group, oolitic limestones of the Inferior and Great Oolite Group, claystones of the Kellaways and Oxford Clay Formations, bioclastic limestones of the Corallian Group, organic-rich mudstones of the Kimmeridge Clay Formation, limestones of the Portland Group and the lower part of the Purbeck Group. The entire sequence presents sedimentation in a shallow water environment. [1]
A complete section is found in the subsurface, but only the upper part of the succession is exposed from Compton Bay to Brighstone Bay and at Sandown Bay, in the core of two broad anticlines. In the Arreton boreholes the Wealden Group reaches a total of 620 m. The exposed sequence comprises the upper part of the Wessex Formation and the overlying Vectis Formation. [1] The Wessex Formation consists of red mudstones with some interbedded sandstones laid down in a freshwater and floodplain environment. The Vectis Formation consists of grey mudstones, deposited in a shallow water lacustrine to lagoonal setting, with some evidence of marine influence. The type section for the formation is in Brighstone Bay.
The Lower Greensand Group marks the return to fully marine conditions in this area. [1]
The Selborne Group comprises claystones of the Gault Formation and sandstones of the overlying Upper Greensand Formation. [1]
The Chalk Group consists of a sequence of chalky limestones with some interbedded marls. The age of the sequence ranges from Cenomanian through to Campanian, The upper boundary is an unconformity across which rocks of Maastrichtian to Paleocene age are missing. [1]
Rocks of Palaeogene age rest unconformably on the Upper Cretaceous sequence on the Isle of Wight. Most of the Palaeocene is missing, in common with all of onshore UK. [1] The Palaeogene strata were deposited in a shallow water marine environment, which was affected by repeated changes in relative sea level, causing cycles of transgression and regression.
The Lambeth Group is well exposed at the southern end of Alum Bay and Whitecliff Bay at the western and eastern ends of the island. This Thanetian (Upper Palaeocene) sequence is represented by the Reading Formation, a thin sequence of mainly claystones with variable amounts of sands, varying from 25 – 40 m in thickness. [1]
On the Isle of Wight this group comprises the Ypresian (lowermost Eocene) London Clay Formation, which reaches up to 160 m in thickness. The formation is a sequence of mainly claystones, although to the east of the island the formation contains sandstones of the Whitecliff and Portsmouth Sand Members. [1]
The Bracklesham Group is of Ypresian to Lutetian in age. Its type section is along the cliffs in Whitecliff Bay. [1]
This sequence is of Lutetian to Priabonian (uppermost Eocene) in age. It comprises a mixture of clays, fine sands, sandy clays and clayey sands. The stratigraphy exposed at the two ends of the island are somewhat different. [1]
The Solent Group is Priabonian to Rupelian (early Oligocene) in age. It comprises the Headon Formation, the Bembridge Limestone Formation and the Bouldnor Formation. [1]
The outcrops of Quaternary age are relatively poorly understood. [1]
Deposition of the Triassic, Jurassic and lowermost Cretaceous sequences was controlled by two large west–east trending, south-dipping normal faults, the Needles Fault and the Sandown Fault, which have an overlapping en-echelon geometry. Reactivation of these faults over part of their lengths during the Paleogene inversion event produced the structures that control the current outcrop patterns.
The two main structures are the Brighstone and Sandown Anticlines, which relate to reactivation of the Needles and Sandown Faults respectively. These anticlines have steep, locally vertical northern limbs, forming the monoclinal structures seen at The Needles, Alum Bay and Whitecliff Bay. In the centre of the island the shortening is transferred between the fault zones, forming the zone of lower dips and north–south strike between Calbourne and Garston's Down. [2] To the north of the monoclines the Paleogene sequence is deformed into a gentle syncline, the Bouldnor Syncline.
The Old Red Sandstone is an assemblage of rocks in the North Atlantic region largely of Devonian age. It extends in the east across Great Britain, Ireland and Norway, and in the west along the northeastern seaboard of North America. It also extends northwards into Greenland and Svalbard. These areas were a part of the ancient continent of Euramerica/Laurussia. In Britain it is a lithostratigraphic unit to which stratigraphers accord supergroup status and which is of considerable importance to early paleontology. For convenience the short version of the term, ORS is often used in literature on the subject. The term was coined to distinguish the sequence from the younger New Red Sandstone which also occurs widely throughout Britain.
The Chalk Group is the lithostratigraphic unit which contains the Upper Cretaceous limestone succession in southern and eastern England. The same or similar rock sequences occur across the wider northwest European chalk 'province'. It is characterised by thick deposits of chalk, a soft porous white limestone, deposited in a marine environment.
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The geology of Hampshire in southern England broadly comprises a gently folded succession of sedimentary rocks dating from the Cretaceous and Palaeogene periods. The lower (early) Cretaceous rocks are sandstones and mudstones whilst those of the upper (late) Cretaceous are the various formations which comprise the Chalk Group and give rise to the county's downlands. Overlying these rocks are the less consolidated Palaeogene clays, sands, gravels and silts of the Lambeth, Thames and Bracklesham Groups which characterise the Hampshire Basin.
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The Hampshire Basin is a geological basin of Palaeogene age in southern England, underlying parts of Hampshire, the Isle of Wight, Dorset, and Sussex. Like the London Basin to the northeast, it is filled with sands and clays of Paleocene and younger ages and it is surrounded by a broken rim of chalk hills of Cretaceous age.
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The geology of West Sussex in southeast England comprises a succession of sedimentary rocks of Cretaceous age overlain in the south by sediments of Palaeogene age. The sequence of strata from both periods consists of a variety of sandstones, mudstones, siltstones and limestones. These sediments were deposited within the Hampshire and Weald basins. Erosion subsequent to large scale but gentle folding associated with the Alpine Orogeny has resulted in the present outcrop pattern across the county, dominated by the north facing chalk scarp of the South Downs. The bedrock is overlain by a suite of Quaternary deposits of varied origin. Parts of both the bedrock and these superficial deposits have been worked for a variety of minerals for use in construction, industry and agriculture.
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