Benton, M.J., Cook, E. and Hooker, J.J. 2005. Mesozoic and Tertiary Fossil Mammals and Birds of Great Britain. Geological Conservation Review Series No. 32, JNCC, Peterborough.
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Bouldnor Cliff exposes the Bembridge Limestone Formation and the Bouldnor Formation
The coastal section at Bouldnor Cliff (including Hamstead Cliff and Ledge) exposes the Bembridge Limestone Formation and all of the overlying Bouldnor Formation in a synclinal structure
The section
Mammal remains, together with fish, turtles and crocodiles, occur at several levels in the Bouldnor Formation: near the top of the Bembridge Marls Member and within the Hamstead Member, both below and above the Nematura Bed. They have been collected from both cliff and foreshore exposures and many arc found loose on the beach with no clear provenance, although preservation can often be a guide. From the Bembridge Marls at Yarmouth several species of large mammal typify the sue–vicum–frohnstettense Zone (Hooker 1987) and Mammal Paleogene Reference Level MP20 (Schmidt-Kittler, 1987), namely Anoplotherium sp., Palaeotherium medium suevicum and Plagiolophus major (Hooker et al., 2004).
Lower parts of the Hamstead Member, below the Nematura Bed, contain similar large mammals, typical of the endemic Late Eocene faunas of Europe, namely Anoplotherium commune, A. latipes, Xiphodon gracilis, Plagiolophus minor, P. major, Palaeotherium magnum, P. muehlbergi and P. curtum frohnstettense. The last is restricted to the suevicum–frohnstettense Zone and MP20. Thanks to screenwashing techniques, a fauna of small mammals has also been found in these strata. Key amongst these is the theridomyid rodent Theridomys bonduelli, whose only other correctly recorded occurrence is in the Marnes Blanches de Pantin in the Paris Basin, affording a secure correlation (Hooker et al., 2004). This correlation integrates with that of the Nematura Bed and Argiles Vertes de Romainville dated on the dinoflagellate cysts (Liengjarern et al., 1980), which form the next higher unit in both basins.
| Thickness (m) | |
| Bouldnor Formation | |
| Cranmore Member (Upper Hamstead Beds of White, 1921) | |
| Corbula Beds | 5.8 |
| Cerithium Beds | 3.4 |
| Hamstead Member (Lower Hamstead Beds of White, 1921) | |
| Green and mottled clays, with lignite beds and shell beds | c. 25 |
| Water-Lily Bed: laminated lignite with seeds, palm leaves, water-lily leaves and molluscs | 0.6 |
| Green and red marls (much obscured) | 20.7 |
| White Band: green clays with white shell-marls | 1.8 |
| Green clay with ironstone nodule band (much obscured) | 10.8 |
| Nematura Bed: black lignitic clay, full of gastropods | 0.9 |
| Green and black clays, with bivalves and gastropods | 8.1 |
| Black Band: lignite, full of Viviparus and Unio | 0.5 |
| Bembridge Marls Member (Bed notation from Daley, 1973) | |
| HAM XXXI–XXXIV: freshwater clays | 1.8 |
| HAM XXX: lignite with seeds and molluscs | 0.1 |
| HAM XXVI–XXIX: clays with seeds and molluscs | 5.7 |
| HAM XXIII–XXV: lignite and clay, rich in water-plant seeds, leaf fragments and gastropods | 2.0 |
| HAM XX–XXII: freshwater clays and silts | 2.0 |
| HAM XIX: green clays and white marls, with bivalves | 0.3 |
| HAM XVI–XVIII: green muds and lignite band | 1.8 |
| HAM XV: black clay with gastropods | 0.2 |
| HAM XI–XIV: muds and silts, with bivalve band | 3.6 |
| HAM VI–X: grey and blue-green laminated clays, with brackish water bivalves and gastropods | 2.7 |
| HAM V: greenish-grey clay with bands containing Melanoides acuta, Serpula sp. and Viviparus lentus | 0.3 |
| HAM I–IV: grey and black clays with Shelly partings and bands containing bivalves and gastropods; thin shell bed with Ostrea at the base (Bembridge Oyster Bed) | 0.9 |
| Rests on Bembridge Limestone Formation |
Upper parts of the Hamstead Member above the Nematura Bed yield a very different fauna. Amongst the large animals, there are no more anoplotheres, xiphodonts or palaeotheres. Amongst the smaller elements, the pseudosciurid rodents, the omomyid primates, the amphilemurid lipotyphlans and nearly all of the nyctitheres have disappeared. In place of the old large mammals are artiodactyls of the families Anthracotheriidae (Bothriodon, Elomeryx and Anthracotherium) and Entelodontidae and a pecoran (advanced ruminant), and perissodactyls of the family Rhinocerotidae (Ronzotherium) (Hooker et al., 2004). Of the rodents, alongside the theridomyids and glirids (dormice), which persisted undiminished, appeared the first European beavers (Asteneofiber), hamsters (Atavocricetodon) and the extinct eomyids (Bosma, 1974; Bosma and de Bruijn, 1979). Also amongst the fauna of smaller mammals are the first European hedgehogs (Tetracus) and bears (a dog-sized amphicynodontine). The upper Hamstead Member has also yielded the last adapid primate in the world (Leptadapis sp.) and the last British nyctithere (one specimen each). In contrast, the marsupials continued almost unchanged.
The anthracotheres, distant hippo relatives, are the best-known elements of the Bouldnor Cliff post 'Grande Coupure' fauna, as they are the only large early Tertiary mammals that are relatively common fossils. Their taxonomy and nomenclature is complex (Owen, 1848c; Lydekker, 1884b, 1885a; Cooper, 1925, 1926a; Lavocat, 1952; Hellmund, 1992; Hooker, submitted). Rare elements represented by only a few isolated teeth are the giant pig-like entelodontid Entelodon (Brunet, 1979) and the first British true rhinoceros Ronzotherium (Ford, 1972).
Shark remains also have been reported from the Cerithium and Corbula beds in the brackish and marine Cranmore Member (Hooker et al., 1980), but no mammals from those levels.
The mammalian fauna from the Hamstead Member at Bouldnor Cliff, consisting of 44 species, is listed here. It is based on information on the rodents from Bosma (1974) and Bosma and de Bruijn (1979), with nomenclatural changes from Vianey-Liaud (1994), Freudenthal (1996) and an updated list by Hooker et al., (2004). The letters (L) and (U) after names distinguish between occurrences in lower and upper parts of the Hamstead Member, respectively.
MAMMALIA
Marsupialia
Herpetotheriidae
Amphiperatherium exile Gervais, 1852 (L,U)
Amphiperatherium minutum (Aymard, 1846) (U)
Amphiperatherium sp. (L, U)
Peratherium cuvieri (Fischer, 1829) (L)
Peratherium elegans (Aymard, 1846) (U)
Peratherium cf. perrierense Crochet, 1979 (U)
Rodentia
Pseudosciuridae
Suevosciurus fraasi (Major, 1873) (L)
Theridomyidae
Pseudoltinomys cuvieri (Pomel, 1853) (L)
Pseudoltinomys gaillardi (Stehlin and Schaub, 1951) (U)
Theridomys bonduelli (Lartet, 1869) (L)
Isoptychus margaritae (Vianey-Liaud, 1989) (U)
Gliridae
Glamys fordi (Bosma and de Bruijn, 1979) (L, U)
Bransatoglis planus (Bahlo, 1975) (L)
Bransatoglis micio (Misonne, 1957) (U)
Eomyidae
Eomys sp. (U)
Cricetidae
Atavocricetodon atavus (Misonne, 1957) (1–1)
Castoridae
Asteneofiber sp. (U)
Lipotyphla
Talpidae
?Eotalpa sp. (L)
Myxomygale cf. antiqua Filhol, 1890a (U)
Erinaceidae
Tetracus aff. nanus (Aymard, 1846) (U)
Plesiosoricidae?
Butselia biveri Quinet and Misonne, 1965 (L, U)
Chiroptera
Vespertilionidae
Stehlinia minor (Revilliod, 1922) (U)
Stehlinia gracilis Revilliod, 1919 (U)
Archonta undiff.
Nyctitheriidae
Paradoxonycteris tobieni (Sigé, 1976) (L, U)
Amphidozotherium aff. cayluxi Filhol, 1877 (L)
Primates
Adapidae
Leptadapis sp. (U)
Pantolesta
Pantolestidae
Dyspterna woodi Hopwood, 1927 (L, U)
Carnivora
Ursidae
?Amphicynodon sp.
Creodonta
Hyaenodontidae
Hyaenodon cf. dubius Filhol, 1873 (U)
Artiodactyla
Entelodontidae
Entelodon magnus Aymard, 1846 (U)
Anthracotheriidae
Elomeryx porcinus (Gervais, 1852) (U)
Bothriodon velaunus (Cuvier in de Blainville, 1846) (U)
Anthracotherium alsaticum Cuvier, 1822 (U)
Choeropotamidae
Tapirulus sp. (U)
Anoplotheriidae
Anoplotherium commune Cuvier, 1804 (L)
Anoplotherium latipes (Gervais, 1852) (L)
Xiphodontidae
Xiphodon gracilis Cuvier, 1822 (L)
Pecora
Pecora indet. (U)
Perissodactyla
Palaeotheriidae
Palaeotherium magnum Cuvier, 1804 (L)
Palaeotherium muehlbergi Stehlin, 1904 (L)
Palaeotherium curtum frohnstettense Franzen, 1968 (L)
Plagiolophus minor (Cuvier, 1804) (L)
Plagiolophus major (Brunet and Jehenne, 1989) (L)
Rhinocerotidae
Ronzotherium cf. romani Kretzoi, 1940 (U).
A distinct change in the nature of the mammal faunas high in the early Tertiary strata in the Isle of Wight was noticed in the pioneering years (e.g. Forbes, 1856). However, it was not until early in the 20th century that the Swiss palaeo-mammalogist H.G. Stehlin (1910), with a European perspective, recognized the scale and significance of this faunal turnover, which he termed the 'Grande Coupure' (meaning 'big break'). During most of the Eocene Epoch, Europe had been a series of islands, intermittently linked, but separated by seaways from other continents. European mammal faunas quickly became endemic and, when Europe and Asia became reconnected early in the Oligocene Epoch, Asian species dispersed into Europe and much of the European endemic fauna (e.g. most palaeotheres, anoplotheriid, xiphodontid and choeropotamid artiodactyls, nyctitheres and primates) became extinct. How much the extinction was due to competition with the newcomers and how much to climatic change (this time was also marked by the first major glaciation of Antarctica in the Cenozoic Era) is still unclear (Hooker et al., 2004).
Until recently, the 'Grande Coupure' in the Isle of Wight was thought to occur between the Bembridge Marls and Hamstead Members of the Bouldnor Formation (e.g. Forbes, 1856; Stehlin, 1910; Hooker, 1992). Intensive collecting, especially using screenwashing, at a number of levels in the Bouldnor Formation has shown that the 'Grande Coupure' is in fact within the Hamstead Member (Hooker et al., 2004). Moreover, a number of taxa previously thought to occur only after the 'Grande Coupure' (e.g. Glamys fordi, Butselia biveri — see Bosma and de Bruijn, 1979; Butler 1972) have been found to pre-date the event, but this does not include any taxa with a clear Asian origin. Stehlin (1910) deduced his 'Grande Coupure' from study of continental European faunas, many of which occur in isolated localities, including fissure fillings, where superposition cannot easily be demonstrated. The Bouldnor Cliff section is thus unique both in having a continuous, well-exposed succession across this faunal divide and in having several discrete levels with a diversity of large and small mammal remains (Hooker et al., 2004).
The Bouldnor Cliff sections have provided the type specimens of two species: Dyspterna woodi Hopwood, 1927, and Glamys fordi (Bosma and de Bruijn, 1979).
The sediments preserved at Bouldnor Cliff are indicative of low-energy conditions and probably were deposited in a mainly lagoonal-lacustrine complex. Salinity ranged from brackish to freshwater. At times the water levels were low and desiccation cracks formed, for example in the lower sections of the Bembridge Marls Member (Daley, 1973). Daley (1973) distinguished three sedimentary environments in the Bembridge Marls Member: estuarine deposits in the lower part, passing up into lagoonal mudstones, and then floodplain and lacustrine sediments at the top. Collinson (1983b) reinterpreted Daley's floodplain lake environment as the upper reaches of a lagoon where salinities had dropped below 3 ‰.
The sample of mammal specimens from the upper part of the Hamstead Member at Bouldnor Cliff includes a relatively high proportion of large animals, which suggests an open habitat (Hooker, 1992). The distribution of dietary preferences and locomotory styles among the mammals suggests a moderately wooded woodland–bushland setting.
The dating of this dominantly non-marine sequence is complex. However, using the combination of a number of different markers (dinoflagellate cysts, mammals and sea-level changes), it is possible to correlate with successions in the Paris and Belgian basins, which have more marine intervals. From these areas, calibration with the standard marine sequences is possible (Liengjarern et al., 1980; Aubry, 1986; Brinkhuis and Visscher, 1995; Steurbaut, 1992). It suggests that the Eocene–Oligocene boundary lies approximately between the Bembridge Limestone and Bembridge Marls and that the 'Grande Coupure' is therefore within the Early Oligocene (Hooker et al., 2004).
The Bembridge Marls and lower Hamstead members are assigned to the suevicum–frohnstettense Zone (Hooker, 1992; Hooker et al., 2004) and Mammal Paleogene Reference Level MP20 (Schmidt-Kittler, 1987). As such, they are age-equivalent of continental European mammal faunas in Spain (Huermeces del Cerro, Sierra Palomera, Villarrosano 1, 12), France (St Capraise-d'Eymet, Tabarly, Baby 2, Villeneuve-la-Comptal, Paris Basin Marnes supragypseuses) and Germany (Frohnstetten, Bernloch 1A, Weissenburg 2). The lower Hamstead fauna is specifically age equivalent of the Marnes Blanches de Pantin in the Paris Basin on the shared presence of Theridomys bonduelli.
The upper Hamstead Member at Bouldnor Cliff is assigned to MP21 (Schmidt-Kittler, 1987) and as such is the age-equivalent of a number of continental European mammal faunas, in Spain (Calaf, Montalban 8, Olalla 4A, Santpedor, Espinosa de Henares), France (Ronzon, Ravet, Ruch, Lagny-Thorigny, Aubrelong 1, Soumailles), Belgium (Hoogbutsel), Germany (Mohren 19, 20, Ehrenstein 1B) and the Czech Republic (Detan (BiochroM'97, 1997)). Its fauna is particularly similar to that occurring at Hoogbutsel (Belgium), with which it shares two rodent species and one lipotyphlan species (Bosma, 1974; Butler, 1972), and with Lagny-Thorigny (Paris Basin) and Ronzon (Central France), where the distinctive anthracothere Bothriodon also occurs (Cavelier, 1979).
The sequence at Bouldnor Cliff is the only one in Europe that shows a well-exposed, superposed succession of multiple pre- and post-'Grande Coupure' mammal faunas, thus accurately documenting the major European faunal turnover just after the Eocene–Oligocene boundary. For this it is important internationally. It is the type locality for two mammal species. Although the cliff sections are much subject to slipping, washing by the sea continues to yield fresh sections and material.