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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D. Huddart
The Quaternary Period is part of the Cainozoic Era and it has been characterized by periodic, major, climatic changes that led to the growth and significant expansion of large ice-caps in the temperate mid-latitudes. The Quaternary Period is divided into the Pleistocene (from 1.6 million years ago (Ma) to 10 000 years ago (ka)) and the Holocene (the past 10 000 years) epochs
The most usual date for the beginning of the Quaternary Period has been suggested as 1.64 Ma, although as defined by the International Union of Geological Sciences (IUGS) it occurs just below the top of the Olduvai magneto-subchron at Vrica in Italy (Aigurre and Passini, 1985), where its age, on an astronomically tuned timescale, is estimated at 1.905 Ma (Shackleton et al., 1990). However, in The Netherlands the preference is for 2.45 Ma and north-west Europe shows a major faunal change at c. 2.5 Ma (Zagwijn, 1974; Gibbard et al., 1991). The Stratigraphic Commission of the International Union for Quaternary Research (INQUA) is currently seeking a suitably defined boundary stratotype and if an age of 2.5 Ma is secured on a sound lithostratigraphical basis, then it will coincide with the appearance of loess in the Chinese stratigraphical record, the first evidence of substantial ice-rafting in the North Atlantic Ocean and the first appearance of Homo habilis in Africa (Bowen, 1999).
Some of the climatic phases of the Quaternary Period have been as warm as, or warmer than the present day, whereas others have been cold enough to generate extensive glacial and periglacial conditions. The evidence in British Quaternary deposits of cold and temperate alternations has formed the traditional division of the period. In the lower part of the land-based sequence the sediments are mainly of shallow-water marine origin. In the later stages, the sediments are largely terrestrial. The overall sequence therefore generally has been interpreted as indicating an initial pre-glacial phase, followed by one when glacial and periglacial environments alternated with temperate ones. Interglacials are temperate, climatic intervals between cold stages, with interstadials representing climatic ameliorations within colder stages. However, the precise number of cold and warmer phases is debatable. Traditionally seven cold stages, together with eight temperate ones, have been recognized in the British Pleistocene record (Jones and Keen, 1993). However, over the past 700 000 years at least six colder phases similar to that of the Last Glacial Maximum are suggested for a deep-sea core (Prell et al., 1986) and there are as many, or more, interglacial climatic fluctuations, similar to, although not notably warmer than, the current prevailing climate
In the British offshore record, on the continental shelf, longer sequences of Pleistocene sediments have been located than on land. Within these longer sequences there are unc onformities and overall the number of stages represented appears to be similar to the traditional land-based record. These traditional British sequences are at variance with the primary worldwide record for climatic change, which is derived from oxygen-isotope analyses and palaeomagnetic studies of deep-ocean core sediments. The sequential variation of the oxygen isotope content in these core sediments is taken to be an indicator of variations in global ice volume.
Periods with different oxygen isotope ratios are identified in the sediment cores and are called 'Oxygen Isotope Stages' (OIS), and these provide the stratigraphical framework
| 1st Edition (1973) | Lithostratigraphy | Aminozone | D-alle/L-Ile$ | Age (ka)† | δ18O and polarity |
| Hailing Member | Hailing | 0.036 ± 0.01 (3) | 10.9 ± 0.12 (14C) | 2 | |
| Devensian | Stockport Formation Δ Upton Warren Member | Upton Warren | 0.07 ± 0.007 (3) | 3 | |
| Cassington Member | Cassington | 0.08 ± 0.009 (6) | ~80 (OSL) | 5a | |
| Ipswichian | Trafalgar Square Member | Trafalgar Square | 0.1 ± 0.001 (11) | 124 ± 5.4 (U) | 5e |
| Ridgacre Formation Δ Kidderminster Member | 159.5 ± 13 (36Cl) | 6 | |||
| Wolstonian | Strensham Court Bed | Strensham | 0.17 ± 0.01 (4) | ~200 (OSL)* | 7 |
| Rushley Green Member | 8 | ||||
| Hoxne Formation | Hoxne | 0.26 ± 0.02 (9) | 319 ± 38 (ESR) | 9 | |
| Hoxnian | Spring Hill Member | 10 | |||
| Swanscombe Member | Swanscombe | 0.3 ± 0.017 (34) | ~400 (U)* 471 ± 15 (TL)* | 11 | |
| Anglian | Lowestoft Formation A | 12 | |||
| West Runton Member | West Runton | 0.35 ± 0.01 (9) | ~500 (ESR) | 13 | |
| Cromerian | Waverley Wood Member | Waverley Wood | 0.38 ± 0.026 (5) | 15 | |
| Kenn Formation Δ | 16 | ||||
| Grace Formation ‡ | Grace | 0.43 ± 0.02 (4) | 810 ± 140 (ESR) | 21 | |
| $ Number of analyses in parentheses
† Age estimate – method in parentheses * Age established at another locality of the aminozone Δ Glacial formation ‡ Somme Valley, France |
Ice cores and loess records provide information complementary to the ocean sediments relating to Quaternary climatic change. Ice cores do not produce as long a record as that from ocean cores, going back only to about 250 ka, but they have a higher temporal resolution, up to the decadal and annual scale in some cases. Climatic records can be reconstructed from such ice cores using a variety of indicators and these have provided detailed climatic reconstructions for the last glacial–interglacial cycle
Overall the various global records indicate that the glacial–interglacial cycles became more marked at about 450 ka and since then, five interglacials have occurred (at c. 400 ka, 320 ka, 200 ka, 120 ka and 10 ka), with four glacials separating them (at c. 340 ka, 250 ka, 150 ka and 20 ka).
Key long-term climatic change records for the north-east Atlantic have been illustrated from continuous deep-ocean cores, for example a composite record of North Atlantic sea-surface temperature change over the past 1.1 million years has been created by joining together data from cores (Ruddiman et al., 1986). This shows an increasing amplitude of sea-surface temperature fluctuations in the more recent section. Progressively colder glacial minima are indicated from 850 ka onwards. During the period 700 ka to 400 ka the interglacial maxima becomes progressively warmer. During this latter period, the amplitude of the dominant cycle (about 95 000 years) increased by a factor of four and the amplitude of the sea-surface temperature fluctuations during the past 400 000 years indicates that temperature differences between glacial maxima and interglacial maxima were 11°C in summer and at least 8°C in winter (Goodess et al., 1991).
This climatic change also has affected eustatic sea levels throughout the Quaternary Period, and because present-day global temperatures are relatively high compared with those over most of the Quaternary, sea levels are too, hiding much of the direct evidence for past sea-level change. There have been advances too in the investigation and dating of earlier Quaternary sea levels. For example, Ikeda et al. (1991) have used the electron spin resonance method to date Middle Pleistocene corals from the Ryuku Islands in Japan. This method is considered to be useful for dating aragonitic corals and for time periods beyond the limits of the uranium-series method. Two high sea-level stands were identified at about 800 ka and 600 ka and they conclude that these are correlated with at least two of the warm marine Oxygen Isotype stages 23, 21, 19, 17 and 15. A similar approach has been used to date the coral reef sequence from Sumba Island, Indonesia (Pira7.7oli et al., 1991). Here there are six terraces broader than 500 m that represent major interglacial periods, together with many smaller terraces. The oldest interglacial stage is dated to around 1 Ma.
High sea-level events identified in the coral reef records also can be identified in the SPECMAP record, indicating a degree of correlation between the two. Indications are that there have been high sea levels at 233, 215, 125 and 100 ka. There is no evidence of a high sea level from the Bahamas record at either 195 or 80 ka (Lundberg and Ford, 1994), whereas high sea levels are indicated by the SPECMAP record
| Stage | Stratotype | Notes |
| Flandrian | Begins 10 ka (14C); base at bottom of pollen zone IV | |
| Devensian | Four Ashes, Staffordshire |
Late: 26–10 ka (14C) |
| Middle: 50–26 ka (14C): includes Upton Warren interstadial complex | ||
| Early: preceding 50 ka (14C): includes Chelford interstadial ~60 ka (14C) | ||
| Ipswichian | Bobbitshole, Ipswich |
Base at beginning of pollen zone II |
| Wolstonian | Wolston, Warwickshire |
Includes Baginton–Lillington gravels, Baginton sand, Wolston series, |
| Dunsmore gravels; base at bottom of Baginton–Lillington gravels | ||
| Hoxnian | Hoxne, Suffolk |
Base at beginning of pollen zone HI |
| Anglian | Corton Cliff, Suffolk |
Lowestoft Till, Corton Sands, Norwich Brickearth/Cromer Till; base at bottom of lower till |
| Cromerian | West Runton, Norfolk |
Upper Freshwater Bed; base at bottom of pollen zone C1 |
| Beestonian | Beeston, Norfolk |
Arctic Freshwater Bed; base at bottom of pollen zone PI |
| Pastonian | Paston, Norfolk |
Gravels, sands and silts; base at bottom of pollen zone BeI |
| Baventian | Easton Bavents, Suffolk |
Marine silt; base at bottom of pollen zone L4 |
| Antian | Ludham, Norfolk (borehole at |
Marine shelly sand; base at bottom of pollen zone L3 (forams: Lv) |
| Thurman | Marine silt: base at bottom of pollen zone L2 (forams: Lm) | |
| Ludhamian | Shelly sand: base at bottom of pollen zone L1 (forams: Ll) | |
| Waltonian | Walton-on-the-Naze, Essex |
Older Red Crag; base at bottom of Crag at Walton |
A record for global sea-level change from this type of work is available for much of the Quaternary Period in various parts of the world, but this is not the case for northern England where the record is detailed only for the Holocene Epoch.
In the British Isles some 14 climato-stratigraphical stages of alternating cold (glacial) and warm (interglacial) conditions