Cox, B.M. & Sumbler, M.G. 2002. British Middle Jurassic Stratigraphy. Geological Conservation Review Series, No. 26, JNCC, Peterborough, ISBN 1 86107 479 4.
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B.M. Cox
The succession at Manton Stone Quarry, in the East Riding of Yorkshire (formerly Humberside), was first described by Ashton (1975) when the section exposed the lower part of the Lincolnshire Limestone Formation and the boundary with the underlying Grantham Formation (see
The details of the section given below are based on Ashton (1975) and a recorded section held on file by English Nature; the lithostratigraphical classification of the Lincolnshire Limestone Formation follows Gaunt et al. (1992). The lowest beds have been seen only in excavations in the quarry floor.
| Thickness (m) | |
| Lincolnshire Limestone Formation | |
| Kirton Cementstone Member | |
| Mudstone, grey, weathered to pale-brown | 0.6 |
| Scawby Limestone | |
| Limestone (pelsparite–biopelsparite), hard, massive, fine grained, grey, weathering honey-yellow, minor marl-mudstone intercalations; ooids and oncoids most common in upper part, those in brown-weathering shale, about 1 m from base, weather from white to brown; most beds have gradational soft, brown, shaly bases; diverse and patchily abundant fauna, mainly bivalves Lucina' bellona d'Orbigny, 'myids' in growth position, oysters, trigoniids), cerithiid gastropods and recrystallized corals; shell debris including bryozoans, echinoderms and serpulids | 2.0 |
| Mudstone, dark-grey, weathering brown, well laminated, slightly bituminous; abundant white, weathering brown, ooids and oncoids | 0.6 |
| Limestone (pelsparite usually with micrite-microspar matrix), hard, grey, splintery, thinly bedded or nodular, poorly fossiliferous, alternating with black or dark blue-grey mudstone-marl; limestones have subsidiary amounts of shell debris, accretionary grains, silt-grade, angular to subrounded quartz grains, and wood, are strongly bioturbated, with rare Pleuromya; abundant Chondrites in both limestones and mudstones, especially at their bed boundaries; mudstones have rich microfauna of ostracods and juvenile oysters, large amounts of montmorillonite, and minor amounts of mica, kaolinite and quartz; small, black, ooid-like grains in lower mudstone beds | 2.35 |
| Santon Oolite Member | |
| Limestone (oopelmicrite with recrystallized matrix), blue-hearted, weathering honey-yellow; well-preserved wood, sometimes bored, in pieces up to 1 m long; elaborate and dense burrow-systems including horizontal, vertical and oblique forms with individual burrows varying up to 10 mm in diameter and highly variable in length | c. 0.7 |
| Limestone (pelmicrite with matrix recrystallized to microspar), cream-coloured with peloids, and sparsely scattered ooids; fossils (mainly concentrated in pockets) including bivalves such as bakevelliids and Pholadomya (in growth position), Natica, Nerinaea, cerithiid and other gastropods, serpulids and crustaceans; burrows (Thalassinoides and Zoophycos) present near top; shell debris | c. 0.9 |
| Limestone (bio-oosparite), yellowish-brown; minor amounts of peloids; becoming increasingly micritic towards top; shelly with bivalve, gastropod and echinoderm debris, and thick-shelled bivalves, mainly preserved convex-side uppermost; beds have retort-shaped burrows in their top c. 0.15 m; gradational base | c. 0.4 |
| Ravensthorpe Member | |
| Variable sequence of buff-coloured limestone (similar to underlying unit but with less quartz), brown clay, and orange-green sand with silt and clay lenses, and wood; Chondrites and large horizontal burrows | c. 1.1 |
| Limestone (variably recrystallized micrite), grey, silty (quartz) with micaceous and clay-rich layers; clays with kaolinite dominant, minor quartz, mica and montmorillonite, and traces of felspar and pyrite; poorly fossiliferous except for abundant burrows (most common in upper part) such as Chondrites, Thalassinoides, Zoophycos | c. 1.3 |
| Mudstone, calcareous, grey with ooid-like grains at base; very shaly at top; mainly kaolinite with minor mica and quartz, and trace of montmorillonite; poorly fossiliferous with small oysters, serpulids and isolated Chondrites | c. 1.3 |
| Cleatham Limestone | |
| Limestone (bio-oosparite), blue-grey, weathering honey-yellow, passing down with decreasing numbers of ooids into biomicrite; micritic matrix largely recrystallized; shell fragments, particularly bivalves and gastropods (notably cerithiids); burrows including Chondrites; oyster-rich, shaly base | c. 1.0 |
| Limestone (biomicrite), hard, grey, porcellaneous | c. 0.3 |
| Limestone (pelmicrite with matrix variably recrystallized), fine grained, silty, grey, weathering yellow-brown; shelly at base with bivalves (small oysters and trigoniids), belemnites and serpulids; trace fossils including large, horizontal burrows; less shelly above with serpulids predominant, and with shell debris, peloids, silt-grade, angular, detrital quartz grains and minor amounts of mica | 0.53 |
| Grantham Formation | |
| Mudstone |
When originally described by Ashton (1975), the basal 0.53 m (Unit A) of the Lincolnshire Limestone Formation was classified as Basal Hydraulic Limestone Member (following Kent, 1966). This member was based on the Hydraulic Limestone of Ussher et al. (1890). However, 1:10 000 scale geological surveying of the Humberside area by the British Geological Survey in the 1960s and 1970s showed that the Lincolnshire 'Hydraulic Limestone' of previous accounts did not extend as far north as previously thought and it was separately named the 'Cleatham Limestone' (Gaunt et al., 1980). In the Manton Stone Quarry section, Gaunt et al. (1992) assigned Ashton's (1975) Unit A and Unit B to this stratum, which they considered as part of the Ravensthorpe Member. Originally, Ashton (1975) had identified his Unit B as the lower limb of the Santon Oolite Member which interfingered with the Ravensthorpe Member, and he proposed the site as the type locality for these two members as well as the underlying Basal Hydraulic Limestone Member.
Gaunt et al. (1992) also named separately a predominantly limestone unit (the Scawby Limestone), which formed the upper half of Ashton's (1975) Kirton Cementstones Member (this member based on Wilson, 1948)
According to Ashton (1975), the section at Manton Stone Quarry provided evidence that the carbonate sea regime, in which the Lincolnshire Limestone Formation was deposited, was at times interrupted by the influence of the delta that occupied the area of North Yorkshire at that time. Supported by observed variations in the quartz content within the succession, and differences in the clay mineralogy between the more clastic-rich (with kaolinite dominant) and carbonate (with montmorillonite dominant) deposits, he suggested that either by southwards prograding or by channel-switching, immature terrigenous clastic sediments were introduced from the north, and not until the retreat or further switching of the delta did carbonate sedimentation re-establish itself.
There are no reliably age-diagnostic fossils reported from this site although, according to Ashton (1975), the brachiopod Acanthothiris crossi (Walker) is widely recorded from the uppermost bed of his Unit F (= Scawby Limestone). Gaunt et al. (1992) cited an ammonite of 'Witchellia type' from that stratum at a locality
Manton Stone Quarry provides a rare section through the lower part of the Lincolnshire Limestone Formation that is unlike the lower part of that formation in the Lincoln, and more southerly, areas. The site is of considerable importance for the interpretation of the local and regional stratigraphy of the formation, as well as palaeoenvironmental analysis that involves the interplay of southerly influenced carbonate deposition and northerly influenced clastic deposition.