Mortimore, R.N., Wood, C.J. & Gallois, R.W. 2001. British Upper Cretaceous Stratigraphy. Geological Conservation Review Series, No. 23, 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
Chapter 6 Inner Hebrides Group, north-west Scotland
Introduction
The Upper Cretaceous sediments of the northwest Highlands were made famous by Bailey's (1924) paper entitled The Desert Shores of the Chalk Seas. The climatic implications for the Late Cretaceous Epoch from this work have been widely debated ever since. Massive cliffs of black, basaltic, Palaeogene lavas irregularly overlie and obscure the Upper Cretaceous deposits, sometimes filling palaeovalleys that have cut deeply through the underlying Mesozoic sediments. These palaeovalleys were presumably cut at the end of the Cretaceous Period following tectonic faulting, uplift and erosion prior to the volcanic outpourings. Consequently the outcrop of Upper Cretaceous sediments is not continuous and this is seen particularly well at the Gribun GCR site on the Isle of Mull, where only small pockets of sediment are preserved, often in landslipped blocks, along the strike. Even where relatively continuous outcrops are present, such as the sea cliffs at Auchnacraig and Carsaig on Mull and the Beinn. Iadain GCR site in Morvern, each exposure shows significant differences in preserved stratigraphy both within the Upper Cretaceous succession and as a result of pre-lava erosion. Many of the exposures are ephemeral stream sections high up slopes beneath the basalts in waterfalls, which can be torrents following rain.
Because the Upper Cretaceous deposits are so thin, there is little significant impact on geomorphology. The sandy deposits of Mull and Morvern overlie Triassic and Jurassic sediments of various ages but where, for example, shales occur beneath the sands, spring lines and saturated ground (bog) are often present. The limestones on Skye provide a different habitat, affecting the flora, which can be picked out as lighter green grassland patches amongst the generally darker green bracken and heather.
Tectonic setting and sedimentary history
The sedimentary succession comprises the Inner Hebrides Group (Braley, 1990; Lowden et al., 1992) and forms part of a Mesozoic Inner Hebrides Basin or Province
Because of the small, discontinuous exposures, it is not possible at this stage, to provide a comprehensive account of the influence of these structures on sedimentation. The evidence, however, for rapid lateral changes in stratigraphy, reworking, debris flows and local preservation windows, suggests that tectonic movements had a marked impact on the Late Cretaceous and Early Palaeogene history of the region.
Stratigraphy
The Inner Hebrides Group is a highly reduced succession, some 2–20 m thick for the inferred Cenomanian to Maastrichtian strata, compared with 110 m in Northern Ireland and 500 m in Norfolk. The succession comprises beds of greensand, white sand, limestones and chalk (in part and, in some places, reworked debris flows), overlain in places by lignite and/or mudstones. Prior to the data published in the present account, the limited fossil records indicated the presence of Cenomanian and, more tenuously, Turonian, Santonian and Campanian sediments. It is remarkable that any sediment remains, and much of it presents evidence of reworking, casting doubt on its age. All of the exposures are very difficult to access and interpret, and most indicate that the sediments have suffered a degree of thermal metamorphism, often calcining or burning important fossil evidence.
Apart from an unpublished PhD Thesis by Braley (1990) and some observations by Rawson et al. (1978), very little significant work has been done since the observations of Judd (1878) and the original [British] Geological Survey memoirs for the area (Bailey et al., 1924; Bailey, 1924; Lee and Bailey, 1925). As part of this review, all of the key sections on Mull, Morvern, Eigg and Skye have been revisited and remeasured, and it is the evidence from these sections that is used in this account, supplemented with observations from previous work, some of it unpublished.
A key part of the succession includes 5 m of limestones near Allt Strollamus on Skye with apparently Turonian foraminifera (Richey et al., 1961; Braley, 1990) and Inoceramus, which may prove crucial to dating the group. A similar limestone may be present at Strathaird, Skye, in Laig Gorge on Eigg, and in the Torosay Quarry section on Mull. Also on Mull, there is a wide variety of sections, ranging from extremely condensed exposures showing reworked material (probable debris flows), to expanded successions with a common stratigraphy, at least in the lower part, comprising Cenomanian greensands. On Eigg, the Cretaceous succession is partly represented by the Clach Alasdair Conglomerate (
Much of the dating of the succession remains controversial, as diagnostic fossils have not yet been obtained from all of the different lithologies. Even the date of the onset of vulcanism at the top of the section is open to question and may be partly Late Cretaceous in age (Kent et al., 1998; Jolley et al., 1998). There are also lignites that are of uncertain age because many of the pollen spores have been burnt-out by the heat from overlying lavas. Only the basal part of the succession, which largely comprises Shelly glauconitic sands, can confidently be dated as broadly Cenomanian in age. There are some similarities in fossil occurrences and lithologies with equivalent sediments in Northern Ireland where the metamorphism is of lower grade and different character. Hence Northern Ireland provides key evidence for unlocking the Hebridean succession.
Despite these uncertainties, the succession, and especially the GCR sites, provide evidence for regional events that are poorly understood at present, such as possible thermal doming prior to volcanic eruption or reactivation of faults during the Late Cretaceous Epoch. The Gribun and Beinn Iadain GCR sites are used as the reference sections against which the other sections in the Inner Hebrides Province are compared and contrasted.
A litho- and biostratigraphy for the Inner Hebrides Group
Judd (1878) proposed the first comprehensive lithostratigraphy for the Inner Hebrides Group. Subsequently, Braley (1990; in Lowden et al., 1992) introduced a number of new units and arranged them in a different stratigraphical order. Braley's nomenclature was followed by the British Geological Survey in the Rhum Memoir (Emeleus, 1997). Because of the great uncertainty about the dates of many of the units, this stratigraphical succession and nomenclature has remained open to question. As a result of the present authors' current work, using the scanning electron microscope to identify and date the nannofossil assemblages, new dates for parts of the succession require a reassessment of the lithostratigraphy
Beinn Iadain (Morvern) and Clach Alasdair (Eigg), which indicate a Late Coniacian or Early Santonian age for these deposits, overlain by Early Campanian silicified pale chalks. Such an age for the phosphates was suggested by Reid (unpublished letters to Dr C.V. Jeans) who dated sponges from the Beinn ladain section collected by Jeans and Platten (Jeans, pers. comm.; Rawson et al., 1978, p. 55). The presence of holococcoliths (Lucianorhabdus cf. cayeuxii Deflandre) in the greensands beneath the Clach Alasdair Conglomerate on Eigg indicates a similar age. Other sediments that must originally have been chalks at Torosay (Mull), Laig Gorge (Eigg), Strathaird (Skye) and Allt Strollamus (Skye) are now cemented dark blue-grey limestones containing abundant coccoliths. Some of these limestones contain nannofossil assemblages indicative of an Early Campanian age (e.g. the nannofossils Prediscosphaera serrata Noel and Micula staurophora (Gartner) Stradner)).
From these studies a broad lithostratigraphy can be established. The succession begins with oyster (Amphidonte)-rich greensands at the base (Cenomanian, probably Mid-Cenomanian, in age) passing up through sandstones with the trace fossil Thalassinoides, and calcareous concretions, immediately followed by oyster (Rhynchostreon)-rich beds with a special form of serpulid (the septagonal Hepteris) which, elsewhere in Europe, is typical of the shallow water sediments that equate with Jefferies' Bed 4 of the Plenus Marls Member. These serpulid and Rhynchostreon oyster-rich sands are overlain by the Lochaline White Sandstone Formation (probably Turonian–Coniacian in age) and then a greensand at the top with phosphates of latest Coniacian or Early Santonian age. Silicified chalks and limestones of Late Santonian–Early Campanian age follow and are in turn overlain by another phase of greensands containing reworked chalk and flint conglomerate. The final part of the succession contains mudstones, shales and lignites and possibly (as on Eigg), reworked earlier lava flows.
The GCR sites contain much of the evidence for this succession but lack the limestones rich in coccoliths. The localities with limestones on Eigg and Skye can be linked to the GCR sites to provide a more complete picture of the Inner Hebrides Group.