Charlesworth points out that terrestrial causes such as deformations of the crust of the earth are not sufficient to have brought about glaciations. He favours the theory that long-term variations in the amount of solar radiation reaching the earth were the probable cause, though it may not be possible to prove their occurrence by direct observation. This hypothesis was first made by Simpson,130 who suggested that an increase in solar radiation by raising the world temperature intensified the atmospheric circulation, and brought about glaciation by augmenting the amount of cloud and precipitation. Charlesworth points out that glaciation was probably produced by a number of factors, of which variation in solar radiation was only one, and that meteorological, geological, and astronomical changes ‘all interacting and so delicately balanced that a slight change, such as would be undetected by less than a century of acute observation, might induce great effects.’
As an outcome of recent studies it is now widely accepted87 that major glaciations are due primarily to the positions of the continents resulting from continental drift and the movements of the tectonic plates. Ice ages can only occur when there are land masses in high latitudes on which ice and snow can accumulate – the condition of the earth today, with an Antarctic continent and an Arctic sea surrounded by land. With the continents in these positions the ‘Milankovitch effect’ comes into operation, and small regular changes in the earth’s orbit and orientation towards the sun cause the rhythmic alternation of glaciations and mild interglacial stages through the changes in the amount of heat received by high latitudes. The ‘wobbles’ in the earth’s movements are astronomically predictable, and consequently the sequence of ice ages can be shown to have occurred many times, probably twenty or more, during the Pleistocene.19 Predictions warn that our present interglacial may not last more than another thousand years until it begins to decline into the next glaciation, which, at its peak after some 20,000 years will be more severe than the Devensian.
‘Little ice ages’, such as the cold period that lasted from about 1650 to 1850, occur at more frequent intervals. They are caused by a temporary decline in sunspot activity combined with an increase in terrestrial volcanic activity, which produces a veil of dust in the atmosphere that reduces the solar heat reaching the earth. Major glaciations, however, only occur when the earth periodically ‘wobbles’ to produce the Milankovitch effect.
Whatever the causes of glaciation may be, we may take it as certain that the present mammalian fauna of the British Isles originated after the end of the great Anglian glaciation nearly half a million years ago. Furthermore it seems probable that few species of mammal survived the Devensian glaciation, during which ice covered the northern part of the islands, and the southern parts were subjected to a severe periglacial climate with permafrost producing frost-tundra having little plant cover. At the end of the Devensian the succeeding Flandrian post-glacial stage saw the establishment of the mammalian fauna as we see it today, although it is now reduced by the loss of several species that have been exterminated by man.
During the last hundred and fifty years a host of geologists and palaeontologists, amateur and professional, has collected great quantities of mammalian fossils from the Pleistocene deposits, and has worked on the difficult problems of deducing the composition of the faunas of the various stages. The earlier workers did not appreciate the importance of recording the exact horizons at which they found the fossils, and consequently their specimens give less information than those collected by later workers who adopted a stricter discipline. In addition, much material collected on sea beaches came from strata exposed in the cliffs above, and cannot be accurately assigned to the horizon from which it is derived. Similarly fossil and subfossil bones found in caves have frequently been excavated without recording the precise horizon from which they came. The stratigraphy of cave deposits is complicated by the way in which the fossils were included. The remains from which the fossils are derived were often washed in by floods, or carried in by predators, so that specimens of different provenance are confusingly mixed.
The researches of many workers nevertheless combine to give a picture of the succession of faunas that can be accepted with confidence as reasonably accurate. The results are widely scattered throughout a vast literature, but the Monographs of the Palaeontographical Society120 in which large numbers of mammalian fossils from the Pleistocene have been described and illustrated during the last hundred and thirty years, deserve special notice. Many authorities, too, have gathered the available information together to give an account of the Pleistocene faunas, one of the earliest being Buckland’s ‘Reliquiae Diluvianae’27 published in 1823, which described fossils from caves and ‘diluvial gravel’ as evidence of ‘the action of a Universal Deluge’. A later classic is Owen’s ‘History of British Fossil Mammals and Birds’ published in 1846,118 and from the nature of the material available necessarily dealing mainly with Pleistocene faunas. In contrast a modern synthesis based on the results of researches supported by the latest technologies such as Stuart’s review,136 shows the complexity of the succession of faunas, and the differences in fauna with the alternation of cold and warm, glacial and interglacial stages. The following summary of events is based in part on this important work.
The deposits of the lower Pleistocene are the strata of the Red Crag, with the Norwich Crag lying above them, that cover much of East Anglia. The oldest part of the Red Crag is the Nodule Bed found at its base in several places. All are marine deposits laid down when the sea level was considerably higher than at present, sometimes as much as forty feet. The fossil bones of land mammals found in them must therefore represent animal carcases that were washed into the sea, especially by rivers in flood, and consequently may not be a fair sample of the contemporary fauna. The Red Crag Nodule Bed, however, is derived partly from the breakdown of older rocks and contains the remains of their fossils in addition to its own contemporary ones; some are derived from Pliocene or older formations and are much worn and polished by wave action.
The alternating temperate and cold stages of the pre-glacial Lower Pleistocene occupied about the first three-quarters of the epoch, some one and a half million years, leaving only half or at most three quarters of a million years for the more spectacular events of the Middle and Upper Pleistocene. The flora of the different stages, and consequently the nature of the contemporary climate, are inferred from a study of pollen analyses and the invertebrate and vertebrate faunas. Throughout this immense period of time the fauna appears to have changed little in composition. The mammalian fossils known from the deposits laid down in the British Isles during the Lower Pleistocene include giant beavers, voles, bears, a panda, hyaenas, sabre-toothed and other cats, elephants and mastodons, horses and zebras, a tapir, rhinoceros, deer and oxen, all of extinct species, together with the still existing beaver and red fox.
This list does not represent a large fauna for so long a period of time but when we remember that, with the exception of a few species known from the cave deposits in Dove Holes, Derbyshire, all are from marine deposits, it is not surprising that it is short. The carcases of animals washed into the sea soon decay and disintegrate so that the bones are scattered and the most durable parts, the teeth, are those more likely to be preserved in marine deposits. The Nodule Bed of the Red Crag, as mentioned above, contains a mixture of fossils. We can well imagine the sea eroding the cliffs of Pliocene or earlier epochs, and then rolling and polishing the released fossils on the beach until they were again buried in new deposits, just as today the fossils of the Crag can be found lying loose on the beach. Some of the fossils thus represent animals that were not members of the Lower Pleistocene fauna, for example the tapir, three-toed horse, and the panda.
The Middle Pleistocene began with a temperate stage, the Pastonian, which was followed by a cold subarctic stage, the Beestonian; this gave way to another temperate stage, the Cromerian, which preceeded the onset of widespread glaciation. The deposits of the Pastonian are marine sands and gravels known as the Weybourne Crag, the lower part of which was laid down in the Baventian stage of the Lower