Huddart, D. & Glasser, N.F. 2007. Quaternary of Northern England. Geological Conservation Review Series No. 25, JNCC, Peterborough, ISBN 1 86107 490 5.
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J. Innes
This site in North Yorkshire is important for preserving lake deposits with a full Late-glacial and early to mid-Holocene record of lithostratigraphical and vegetational history from the Vale of York, a region from which relatively few long environmental records are available. Sediments occurring within a hollow in the Escrick Moraine near Tadcaster have been investigated using pollen and plant macrofossil analysis (Bartley, 1962), and more recently using insect remains, to study Late-glacial climate change (Lowe et al., 1994a, b). The Late-glacial sediments have been classified within the Bingley Bog Formation by Thomas (1999). The site has been discussed during a recent wetland survey of the Vale of York (Van de Noort and Davies, 1993; Gearey and Lillie, 1999; Lillie and Gearey, 1999), and has been important for studies of Late Devensian deglaciation in this area (Gaunt, 1981). Tadcaster is one of the first sites in Britain from which pollen evidence for early Late-glacial climate change was reported.
The site lies 1 km to the south-east of Tadcaster in the southern Vale of York, and 0.5 km north of the River Wharfe. It comprises a hollow up to 6.5 m deep containing lake sediments within the Escrick Moraine, an arcuate till ridge that extends from west of Tadcaster to beyond the River Derwent at the foot of the Yorkshire Wolds, at the eastern edge of the Vale of York (Catt, 1977d, 1991b). The moraine is composed mainly of till (Gaunt, 1970a), with some glacial sands and gravels on its north-westerly side. The small lake basin has been drained in recent times by a tunnel through the glacial sediments to the River Wharfe (Edwards et al., 1950) and it today forms an area of flat meadowland with a dry, silty surface soil.
Bartley (1962) examined the stratigraphical succession in the basin by a lateral transect of twenty-five hand cores, which proved a sequence of mainly limnic sediments, overlying the undulating surface of the basal pebble-rich sandy clay diamicton
Above this lower clay and mud sequence there are three organic elements that characterize the mid-profile lithostratigraphy. To the north of the section there is a layer of peat that contains abundant bark, twigs and wood in its central part but which includes an increasing proportion of detrital mud towards its lower and upper contacts. Pinus wood occurs in the central peat, whereas Populus is recorded in the lower muddy levels and Alnus and Betula in the upper muddy zone. Macrofossil remains of aquatic herbaceous plants Cladium, Carex, Potamogeton, Phragmites, Scirpus and Nymphaea are very common in various levels of this peat. In the centre of the basin this peat is not present, and instead there are two contrasting limnic mud layers at this depth in the sequence. A dark brown, highly amorphous mud is the lower and thicker of these two, and it contains very few plant remains. Fruits and seeds of Alnus, Betula pubescens, Betula verrucosa, Nymphaea, Carex, Ceratophyllum demersum and Najas marina do occur. This dark amorphous mud overlaps the peat. The third element is a much thinner layer of light brown mud, which rests upon the amorphous mud and overlaps the woody peat nearer the margins of the basin, where the amorphous mud is absent. This upper mud contains abundant plant macrofossils, including Alnus, Carex, various Potamogeton species, Cicuta virosa and Nymphaea alba.
The uppermost sequence of deposits is present in the centre of the basin only, where the surface of the limnic mud layers is concave in shape and upon which firstly fresher brown Sphagnum, and then more humified Sphagnum and Eriophorum peats have accumulated, both containing wood remains of Alnus, Betula and Calluna. The fresher Sphagnum peat is composed mainly of S. cuspidatum and contains fruits and seeds of Nymphaea and Potamogeton. The upper, more humified, peats contain abundant Eriophorum vaginatum cuticles, and Sphagnum plumulosum remains. A peaty, silty mineral soil seals the sequence across the whole of the basin.
Bartley (1962) constructed pollen diagrams through the northern part of the transect at core 14, where a fully representative sequence of sediments was preserved. These diagrams are shown as Figure 6.21 and Figure 6.22.
Ia Low Betula values, with B. nana consistent at around 10% of total pollen. Cyperaceae and Gramineae contribute more than 50%. Some thermophilous pollen, such as Corylus, is present in low numbers. Many open-ground herbaceous taxa occur, most commonly Artemisia, Rumex acetosa-type , Rubiaceae and a range of aquatic types. Lycopodium selago is prominent.
Ib Betula pollen rises to about 25%, and Gramineae pollen falls in proportion. Juniperus and Thalictrum, more thermophilous types, become consistently recorded.
Ic Betula frequencies fall again to a minimum of 6%, whereas Gramineae values are almost restored to their previous abundance. Other herbs such as Helianthemum increase, but percentages of most taxas remain steady. Juniperus frequencies increase in this sub-zone, and rise to a sharp peak of 44% near the top.
II This zone, which corresponds stratigraphically to the lower calcareous mud layer, includes the disappearance of Juniperus pollen and a rise in Betula to almost 50% of total pollen. Pinus also becomes significant. Betula nana is not always present and herb pollen taxa, in general, are much reduced. Filipendula is an exception, and has high values throughout the zone.
III Betula values decline to about 20%, but B. nana increases. There is a sharp increase in Cyperaceae percentages, not mirrored in the Gramineae curve. Artemisia, Thalictrum and Rumex acetosa-type are present in high values, and Lycopodium selago reappears.
IV Characterized by a great increase in Betula frequencies to almost 80% of total pollen (over 90% of total tree pollen). Betula nana is no longer recorded and Cyperaceae almost disappears. Filipendula rises sharply and aquatics also increase. Other herb pollen types are reduced to only sporadic counts.
The Holocene pollen record above zone IV initially is confused and perhaps reflects some contamination by later sediment as small peaks of Alnus, Ulmus and Quercus occur prior to the rise in Corylus pollen, which usually delimits the start of Boreal assemblage zone V Typical mid-Holocene tree pollen changes do occur above this confused zone, however, with Corylus, Pinus, Ulmus, Quercus, Alnus and Tilia rising to high values in turn, and Betula gradually declining to very low frequencies by the top of the profile. Pinus also falls to low values after the Alnus rise. Herb pollen taxa are almost absent after the Corylus rise.
Much of the importance of the deposits at Tadcaster lies in their location atop the Escrick Moraine, which is a key stage in the process of the southerly advance of the main ice lobe down the Vale of York. Some initial ice advance to the south of this moraine into glacial Lake Humber took place (Gaunt, 1981), perhaps as far as the Doncaster area (Catt, 1991b). It deposited glacial gravels upon a periglacial land surface, which extends northwards beneath the Escrick Moraine itself (Gaunt, 1976; Catt, 1991b), before ice-sheet retreat to the Escrick line. It therefore is unlikely that the Escrick Moraine represents a true terminal moraine and static ice front (Catt, 1977d; 1991b). It does, however, mark an important stage in the Vale of York deglaciation. The start of sediment accumulation within the Tadcaster hollow must have been of an age only slightly younger than the beginning of ice withdrawal from the Escrick Moraine and so could provide a limiting date for retreat from this depositional limit. Dating must be relative, however, based upon pollen assemblages, a deficiency that applies to the rest of the profile also, including the later organic sediments. The site is unique in the southern Vale of York in preserving a complete Late-glacial sequence, and historically was one of the first sites where a very early Late-glacial zone I vegetation history was recognized. Only a few sites in northern England have since yielded a comparable record.
Pollen zones Ia and Ib represent an amelioration of climate after deglaciation, at first gradual then more rapid. Initial pioneer colonizing vegetation of grasses, sedges, dwarf birch and abundant ruderal herbs, such as Artemisia, reflect tundra-type conditions and dominate zone Ia. The site is undated, but the grass–sedge tundra environments of the earliest zone, Ia, must date prior to the general onset of rapid climatic warming at the start of the main Late-glacial Interstadial, which can be correlated with zone Ib. Gradually these early cold-tolerant tundra-type communities gave way in zone Ib to an open birch woodland, with a rich ground flora of tall herbs with some, such as Thalictrum, indicating a warmer climate and more developed soil conditions. This vegetation succession towards woodland communities is reversed in zone Ic, with the return of grass, sedge and open-ground herb taxa to dominance and the major reduction of tree birch cover. A climatic 'reversion' and a return to colder conditions, although probably not as cold as in early zone Ia, may well have been responsible, although as Tipping (1991a) has pointed out, the Tadcaster pollen data remain equivocal as evidence of vegetational, and therefore actual climatic, reversion. The Tadcaster pollen assemblages are not easy to interpret and possibly could result from taphonomic and other factors, representing a unidirectional vegetation succession. There is no supporting signal in the lithostratigraphy of changed conditions in the catchment. Recent work on Greenland (GRIP) ice cores and other proxy data, however, has recorded a short-lived episode of colder temperatures in the Late-glacial Interstadial about 12 000 years BP, which supports the climate 'reversion' theory (Walker et al., 1994; Bjork et al., 1998). Although birch trees probably did not disappear from the area during this zone Ic colder phase at Tadcaster, conditions for their existence must have been marginal at best. The great expansion of jumperus towards the end of this phase, however, shows that although this short climatic deterioration was significant enough to suppress tree growth, it was not severe enough to prevent colonization by juniper-dominated shrub communities and the rapid re-establishment of tree birch woodland when amelioration ensued.
Tadcaster zone II is a typical main Late-glacial Interstadial (cf. Allerød) warm climate environmental record, with the rapid spread of birch trees to cover the landscape and shade outJuniperus virtually entirely. Filipendula is the only herb to be favoured during this phase, reflecting its thermophilous character, and the major decline of all other herb taxa demonstrates the closed nature of the woodland on the drier lands around the site. Most surviving herb types probably had wetland associations. Dates of between 13 000 and 11 000 years BP are inferred for this interstadial, which incorporates the traditional Bolling and Allerød continental warm periods, from many dated sequences elsewhere (e.g. Walker et al., 1993, 1994). The sharp fall in Betula tree pollen in zone III and its replacement by a cold-tolerant, sedge tundra-type, herbaceous flora in which grasses, sedges and Artemisia are prominent, correlates with the Younger Dryas (Loch Lomond Stadial) arid period of severe cold between 11 000 and 10 000 years BP (Walker et al., 1993). Sparse vegetation cover encouraged soil instability and erosion and in most sites sedimentation at this time is clastic in nature. In this respect the lithostratigraphy at Tadcaster supports the pollen stratigraphy in that the periods of conspicuously warmer climate and more developed vegetation of zones II and N correlate with more organic mud layers, whereas the colder phases are times of blue lake clay deposition. The end of the zone III cold phase and the start of the Holocene (zone IV) is defined by the very rapid expansion of full Betula woodland, with very few open-ground indicators. This transition was achieved without any intervening transitional Juniperus phase, unlike several sites farther to the north, such as those in east Durham (Bartley et al., 1976), but similar to nearby Bingley Bog (Keen et al., 1988).
Tadcaster is highly significant in that it contains the dual Betula maximum in the Late-glacial succession, with the earlier Betula peak allowing the subdivision of Late Devensian zone I at the site. Dating of this earlier of the Late Devensian Betula peaks at Tadcaster is still uncertain, but correlation with the start of the main Late-glacial Interstadial would mean that it is almost certainly in the order of 13 000 years BP indicated by radiocarbon evidence from sites in the region, such as Gransmoor (Walker et al., 1993). At Tadcaster, as in northern England in general, a birch woodland became established in this earlier interstadial phase, which was lighter than that of the later, zone II, woodland biozone. A dual Late-glacial Betula peak subsequently has been recognized at other sites in the area, such as The Bog, Roos in Holderness (Beckett, 1981), Seamer Carrs and Kildale Hall on the western edge of the North York Moors (Jones, 1976a, 1977b) and Thorpe Bulmer in east Durham (Bartley et al., 1976). Surprisingly, thermophilous pollen grains occur throughout the Late-glacial record at Tadcaster, explained by Bartley (1962) as the result of reworking. This probably is the case, but Keen et al. (1988) have recorded similar thermophilous pollen in Late-glacial contexts, which they ascribe to long-distance transport from refugia to the south. Growth of these taxa, for example Corylus, near to Tadcaster in the early Late Devensian seems very unlikely, although Late-glacial Alnus macro-fossils from Willow Garth in east Yorkshire (Bush and Hall, 1987) suggest such records cannot be dismissed.
The Holocene environmental record at Tadcaster is unexceptional and also truncated, finishing in mid-Holocene post Alnus rise, pre-Ulmus decline (Flandrian II) times (Lillie and Gearey, 1999). The successive immigration of thermophilous trees Corylus, Pinus, Ulmus, Quercus, Alnus and Tilia follows a pattern repeated in the other sites in the Vale of York, varying according to local environmental factors. Nearby analogous records are Burton Salmon (Norris et al., 1971) and Askham Bog (Gearey and Lillie, 1999). The demise of Pinus at Tadcaster after the Alnus rise suggests that these two factors are linked, and this supports the view of Bartley (1962) that the macrofossil content and lithostratigraphy of the upper sediments record a major change from a zone VI dry depositional surface to its replacement in zone Vila by flooding and deeper water. The peats of zone VI age carried pine trees in the upper layers and the contemporaneous dark oxidized limnic mud in mid-basin also points to low water tables. After the Alnus rise, however, the light brown mud with abundant aquatic plant-remains reflects deep water, followed by a succession to wet Sphagnum swamp peat. This appears to be a very clear record of mid-Holocene climate change.
Tadcaster is a classic site in the early study of Late-glacial vegetation and climate change in Britain, providing the earliest analysed, full, pollen record for the tripartite stadial-interstadial-stadial succession. Its evidence of two warm phases encouraged further subdivision of this succession and the recognition that more than one, or at least one complex, Late-glacial Interstadial existed in Britain. This allowed correlation with the data from continental northwest Europe and with its system of classification. Much more detailed research is now available for the history of climate and vegetation change in the British Late-glacial, and the Tadcaster site requires renewed and detailed examination to fulfil its clear potential.