Cossey, P.J., Adams, A.E., Purnell, M.A., Whiteley, M.J., Whyte, M.A. & Wright, V.P. 2004 British Lower Carboniferous Stratigraphy. Geological Conservation Review Series, No. 29, JNCC, Peterborough. The original source material for these web pages has been made available by the JNCC under the Open Government Licence 3.0. Full details in the JNCC Open Data Policy
Yeathouse Quarry, Cumbria
Introduction
The Yeathouse Quarry GCR site, near the village of Frizington, 7 km east of Whitehaven, includes the small quarry at Yeathouse
Description
At the south-east end of the site, on the northeast side of the old railway on the slope down to Windergill Beck
Between the unconformity and the entrance cutting to Yeathouse Quarry, parts of the Holkerian Seventh Limestone (= the Frizington Limestone Formation of Barclay et al., 1994) containing Lithostrotion can be seen. Directly overlying the Basement Beds are coarse sucrosic dolomites and sandy packstones with hummocky cross-stratification (N. Riley, pers. comm., 2002) interbedded with a few homogeneous grey carbonate mudstones. Above this, thin beds of cross-stratified fine-grained sandstone appear. To the north-west of the site of Yeathouse Station, 7 m of cherry, argillaceous limestones occur, interbedded with fine sandstones and siltstones. These are presumed to lie high up within the Seventh Limestone.
The most recent sedimentological work on the Asbian successions of north and west Cumbria is that of Thurlow (1996) and the descriptions and interpretations that follow are based on his logs (see
The Fifth Shale, also known as the 'Chonetes Shale', is 9 in thick at Yeathouse and consists of two terrigenous clastic units separated by a unit of crinoidal wackestone and packstone. The lower terrigenous clastic unit is a dark-grey to black shale with thin horizons crowded with chonetoids, productoids and productoid spines. The upper unit comprises interbedded mudstones and very fine sandstones. Mudstones are bioturbated by Planolites and are rich in plant debris; sandstones are calcite-cemented and have gutter casts on their bases, hummocky cross-stratification within and rippled tops. The Fifth Shale at Yeathouse is the type horizon for the trilobite Linguaphillipsia cumbriensis, described by Riley (1984).
The Fifth Limestone at this site is 16 m thick. The base is seen at the mouth of the cutting leading into the quarry, where it is rather sandy. In the quarry face, highly fossiliferous, somewhat bituminous limestones pass upward into paler-coloured, coarser, grainy limestones. The fauna includes corals (Siphonodendron, Lithostrotion, Syringopora, Palaeosmilia, Dibunophyllum), crinoid fragments, brachiopods, bivalves and gastropods. Thalassinoides burrows are prominent in the lower part of the limestone. The succession is punctuated by a thin grey-green palaeosol clay. Terrigenous clastic beds attributed to the Fourth Shale occur In the southwestern corner of the quarry, but are not easily accessible. They comprise mostly vari-coloured (grey-green and purple) silty mudrocks and fine silty sandstones. The White Limestone rests with a sharp contact on these beds. Only the lowest beds are seen and they comprise pale-coloured crinoidal packstones and grainstones.
Interpretation
According to Akhurst et al. (1997), the thin basal red-bed succession consists of locally derived Lower Palaeozoic material deposited on a coastal alluvial plain and in fluvial channels. The Seventh Limestone at this site is poorly exposed and partly dolomitized, making it difficult to determine depositional environments in detail, but it most probably represents the deposits of a storm-influenced shallow sea which gradually became established across the Lake District Block.
Cyclicity is a feature of Asbian shelf sequences everywhere in Britain. Those of the Asbian succession in west Cumbria are rather more complex than many elsewhere as a result of the significant terrigenous clastic input. Thurlow (1996) recognized six cycles in the 'early' Asbian sequence of west Cumbria, with cycles 2–6 present at Yeathouse, cycles 2–5 in the Sixth Limestone, and the Fifth Shale comprising cycle 6. Each cycle broadly records upward shallow-ing, sometimes with evidence for subaerial exposure at the top. The beginning of the following cycle shows evidence of deepening compared with the upper part of the preceding cycle, although a transgressive unit may be present. For example, cycle 6, the Fifth Shale, begins with shales deposited in an offshore, variably anoxic environment. This is followed successively by subtidal carbonates that show some evidence of shallowing, by clastic deposits of a shallow storm-dominated shelf, and by lower shoreface sandstones (Thurlow, 1996). The occurrence of coarse dolomite in the middle of the Sixth Limestone may be related to local faulting (Thurlow, 1996).
The Fifth Limestone and Fourth Shale make up two shallowing-upward cycles, the first consisting entirely of limestone capped by a palaeosol clay and the second consisting of limestone capped by the alluvial deposits that make up the Fourth Shale.
Conclusions
This site is important for showing the unconformity between the Dinantian succession and the Skiddaw Group. It also displays a near-complete section through the disputed early Asbian succession and good exposures of the late Asbian Fifth Limestone. It is particularly valuable for the study of Asbian cycle style in a mixed clastic-carbonate shelf environment.