Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-16T03:24:15.649Z Has data issue: false hasContentIssue false

Luminescence dating of a late Middle Pleistocene glacial advance in eastern England

Published online by Cambridge University Press:  29 November 2021

Philip L. Gibbard*
Affiliation:
Scott Polar Research Institute, University of Cambridge, Lensfield Road, CambridgeCB2 1ER, England, UK
Mark D. Bateman
Affiliation:
Department of Geography, University of Sheffield, SheffieldS10 2TN, England, UK
Jane Leathard
Affiliation:
Department of Geography, University of Sheffield, SheffieldS10 2TN, England, UK
*
Author for correspondence: Philip L. Gibbard, Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Previous investigation of isolated landforms, on the eastern margin of the East Anglian Fenland, England, has demonstrated that they represent an ice-marginal delta and alluvial fan complex deposited at the margin of an ice lobe that entered the Fenland during the ‘Tottenhill glaciation’ (termed the ‘Skertchly Line’). They have been attributed, based on regional correlations, to a glaciation during the Late Wolstonian (i.e. Late Saalian) Substage (Drenthe Stadial, early Marine Isotope Stage (MIS) 6). This paper aimed to test this correlation by directly optically luminescence dating, for the first time, sediments found within the Skertchly Line at Shouldham Thorpe, Norfolk, and Maidscross Hill, Suffolk, together with those in associated kame terrace deposits at Watlington, Norfolk. Ages ranged from 244 ± 10 ka to 12.8 ± 0.46 ka, all the results being younger than MIS 8 with some clearly showing the landforms have been subsequently subjected to periglacial processes, particularly during the Late Devensian Substage (∼MIS 2). Most of the remainder fall within the range 169–212 ka and could be assigned to MIS 6, thus confirming the previously proposed age of the glaciation. The local and regional implications of these conclusions are discussed, the maximum ice limit being linked to that of the Amersfoort–Nijmegen glaciotectonic ridge limit in the central Netherlands.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press

Introduction

In a series of articles over the last two decades (Gibbard et al., Reference Gibbard, West, Andrew, Pettit, Lewis, Whiteman and Bridgland1991, Reference Gibbard, West, Andrew and Pettit1992, Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Gibbard, West, Boreham and Rolfe2012a, Reference Gibbard, West, Boreham and Rolfe2012b, Reference Gibbard, West and Hughes2018; West et al., Reference West, Gibbard, Boreham and Rolfe2014; Gibbard, Reference Gibbard, Lewis, Whiteman and Bridgland1991), evidence has emerged indicating that the Fenland region of East Anglia, England, was glaciated during the late Middle Pleistocene. The detailed investigation of the setting, morphology and internal architecture of a line of hills adjacent to the eastern Fenland margin demonstrated that they represent a series of ice-contact fan deltas, a subaerial glaciomarginal alluvial fan and in one case a subaerial kame terrace-like deposit (grouped as the Feltwell Formation: Gibbard et al., Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Gibbard, West and Hughes2018). The accumulations mark a distinct maximum glacial limit termed the ‘Skertchly Line’; Figs. 1a, b and 2), identified in the series studies, noted above. This complex of landforms was formed where an ice lobe, flowing from the north to north-west, dammed a series of local streams on its eastern and south-eastern flank to form a proglacial lake in contact with the ice front. The ice-contact fan deltas and a subaerial alluvial fan were deposited where meltwater discharged from tunnel portals in the ice. The ice-contact (glaciomarginal) deltas accumulated in a lake that was recognised first by Paterson (Reference Paterson1939, Reference Paterson1942), termed ‘Lake Paterson’, that initially drained through the Little Ouse–Waveney valleys, and to the southern North Sea basin, whilst the second more northerly lake was dammed in the Nar valley (Gibbard et al., Reference Gibbard, West, Andrew, Pettit, Lewis, Whiteman and Bridgland1991; Reference Gibbard, West, Andrew and Pettit1992) (Fig.3). This ‘Tottenhill advance’ (Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004; Lewis and Rose, Reference Lewis, Rose, Lewis, Whiteman and Bridgland1991; Clark and Gibbard, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011; Gibbard et al., Reference Gibbard, West and Hughes2018; Turner et al., Reference Turner, Gibbard and West2020) was determined to be of Late Wolstonian age (i.e. Late Saalian, within Marine Isotope Stage (MIS) 6). Despite suggestions that the marginal deposits had been previously interpreted as remnants of an older fluvial terrace, they have been shown to be of ice-marginal origin (see discussion in Gibbard et al., Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Gibbard, West, Boreham and Rolfe2012a, b; Turner et al., Reference Turner, Gibbard and West2020), their age was confirmed by multiple lines of evidence, including previously determined optically stimulated luminescence (OSL) ages from individual localities (c. 160 ka), including from Warren Hill (Three Hills) and Tottenhill, Norfolk (cf. below) and the presence of an interglacial palaeosol developed on the deposits’ surface (Gibbard et al. Reference Gibbard, West, Andrew, Pettit, Lewis, Whiteman and Bridgland1991, Reference Gibbard, West, Andrew and Pettit1992, Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Davies, Roberts, Bridgland, Ó Cofaigh, Riding, Demarchi, Penkman and Pawley2012; Gibbard, Reference Gibbard, Lewis, Whiteman and Bridgland1991; Lewis and Rose, Reference Lewis, Rose, Lewis, Whiteman and Bridgland1991; Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004; Clark and Gibbard, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011; West et al., Reference West, Gibbard, Boreham and Rolfe2014; Pawley et al., Reference Pawley, Bailey, Rose, Moorlock, Hamblin, Booth and Lee2008, Pawley, personal communication). This evidence has demonstrated that the Skertchly Line deposits and landforms are intermediate in age between the Hoxnian (Holsteinian; c. ?MIS 11c; cf. Ashton et al., Reference Ashton, Lewis, Parfitt, Penkman and Coope2008) and Ipswichian (Eemian; c. MIS 5e) interglacial stages (Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004; Gibbard et al., Reference Gibbard, West, Andrew, Pettit, Lewis, Whiteman and Bridgland1991, Reference Gibbard, West, Andrew and Pettit1992, Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Gibbard, West and Hughes2018; Lewis and Rose, Reference Lewis, Rose, Lewis, Whiteman and Bridgland1991; Clark and Gibbard, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011; West and Gibbard, Reference West and Gibbard2021). This glaciation greatly influenced the subsequent evolution of the Fenland basin and drainage systems and landscape morphology throughout the region, especially the English Midlands, glaciated during this event.

Fig. 1. a. Location map showing western East Anglia and the Fenland basin study area. 1b. The proposed glaciation limits for eastern England based on Clark and Gibbard (Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011) and Gibbard et al. (Reference Gibbard, West and Hughes2018) (solid lines), the limit for the possible Middle Wolstonian ‘MIS 8’ glaciation postulated by White et al. (Reference White, Bridgland, Westaway and Straw2017) (dotted line). For site localities see Fig. 1a.

Fig. 2. Quaternary geological map of the study region, showing the glacial deposits, gravel spreads and the Fenland Holocene deposits. The approximate ‘Skertchly Line’ glacial maximum limit is also shown. Map source: EDINA.

Fig. 3. Schematic palaeogeography showing the maximum extent of the Tottenhill glacial lobe in Fenland (Late Wolstonian Substage) and associated drainage alignments and glacial lakes (modified from Gibbard et al. Reference Gibbard, West and Hughes2018). The blue arrows indicate the direction of ice advance. For site localities see Fig. 1a.

Based on extensive preserved evidence, during the Middle Pleistocene Anglian Stage (Elsterian Stage, c. Marine Isotope Stage 12; Table 1), ice extended across all of East Anglia as far south as the Thames Valley, as well as offshore in the southern North Sea and Irish Sea basins (Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004). An extensive ice sheet also existed during the Devensian Stage (MIS 2/3) when ice extended south in the North Sea as far as the Norfolk coast (Roberts et al., Reference Roberts, Evans, Callard, Clark, Bateman, Medialdea, Dove, Cotterill, Saher, Cofaigh, Chiverrell, Moreton, Fabel and Bradwell2018). Intermediate between the Anglian and Devensian glacial events, a Wolstonian-age glaciation was originally identified in the English Midlands (e.g. Shotton, Reference Shotton1953; Rice, Reference Rice1968) and subsequently recognised in Yorkshire, Lincolnshire and northern East Anglia (Clark and Gibbard, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011). At many places, however, Wolstonian-age glacial deposits were thought by some to pre-date the stage. This was particularly the case in East Anglia where there has been considerable controversy concerning the number of glaciations, their extent and relationships of glacial sequences one to another, particularly in recent years (e.g. Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004; Straw, Reference Straw2005, Reference Straw2011; White et al., Reference White, Bridgland, Westaway, Howard and White2010, Reference White, Bridgland, Westaway and Straw2017; Clark and Gibbard, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011; Turner, Reference Turner, Gibbard and West2020: Fig. 1b). Resolution of these issues has been problematic because evidence of the extent and stratigraphical relationships of the Wolstonian glaciation are only poorly preserved in the eastern English Pleistocene record as a consequence of later erosion and disagreements over the age dating (Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004).

Table 1. Geological timetable of events in the Fenland region, eastern England, and their correlation to the near Continent during the Middle to Late Pleistocene subseries (modified from Gibbard et al., Reference Gibbard, West and Hughes2018). The NW European chronostratigraphy/climatostratigraphy is modified from Litt et al. (Reference Litt, Behre, Meyer, Stephan and Wansa2007, Reference Litt, Schmincke, Frechen, Schlüchter and McCann2008) and Roskosch et al. (Reference Roskosch, Winsemann, Polom, Brandes, Tsukamoto, Weitkamp, Bartholomäus, Henningsen and Frechen2015). For further explanation see the text.

Dating of the Tottenhill glacial advance to the Skertchly Line complex in Fenland to the Late Wolstonian Substage (i.e. Late Saalian Substage, ∼MIS 6) was based primarily on litho- and morphostratigraphical relationships in the region, bracketing ages and the presence of an interglacial palaeosol developed on the deposits’ surface (Gibbard et al., Reference Gibbard, West and Hughes2018 and the references therein). This clearly marks it as distinct from the earlier Anglian glaciation. However, published numerical ages on Tottenhill glacial deposits are absent apart from a preliminary assay (without uncertainties) of c. 160 ka reported in Gibbard et al. (Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009). Nearby on the Norfolk coast at Stiffkey, recent work on the moraine landform deposits there reported ages of 141 ± 9.4 and 165 ± 11 ka (Evans et al., Reference Evans, Roberts, Bateman, Ely, Medialdea, Burke, Chiverall, Clark and Fabel2019) indicating at least regional presence of ice within MIS6, although this may not necessarily be the same event as the Tottenhill glacial advance.

Based on quarry exposures at Maidscross Hill, Suffolk, and Shouldham Thorpe and Watlington, near Tottenhill, Norfolk, this article presents the results of numerical luminescence age determinations of the series of gravel and sand accumulations that underlie the characteristic ‘Skertchly Line’ landforms. Previous detailed geological and geomorphological investigation of landforms, supported by a ground-penetrating radar (GPR) investigation of unexposed areas, demonstrated their origin as glaciomarginal accumulations. The aim was to determine whether the attribution of the Tottenhill glacial advance to MIS 6 could be geochronologically substantiated. The regional implications of the findings are presented herein.

Sample site successions

The investigation of the sites undertaken during this study is summarised below. The descriptions include standard facies codes (modified from Miall, Reference Miall1978; Eyles et al., Reference Eyles, Eyles and Miall1983). Summary site descriptions only are presented. For full details, reference should be made to Gibbard et al. (Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009; Reference Gibbard, West, Boreham and Rolfe2012a, b).

Maidscross Hill (Lakenheath), Suffolk

Maidscross Hill (The Broom), east of Lakenheath (National Grid Reference – TL 725826), reaches an altitude of 31 m OD (Fig. 4). The deposits were exposed in a large pit on the SE side of the hill adjacent to the RAF Lakenheath NW boundary. Here, vertical test pits were dug and sections revealed and cleaned. A composite log is given in Fig. 4. The artefact-bearing sediments here have been investigated since the mid-nineteenth century (cf. Gibbard et al., Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009 for details).

Figure 4. Luminescence sample localities for the Maidscross Hill site with the approximate positions of IRSL samples and pIRIR225 ages shown on the stratigraphic log of Gibbard et al (Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009).

The sedimentary succession at Maidscross Hill rests on bedrock Chalk, the basal sediments comprising laminated granular fine sands with chalk fragments (facies Sh) at least 20 cm in thickness (in borehole at the base). They are conformably overlain by horizontally stratified medium sand with silt laminae and coarsening upwards to pebbly cross-bedded medium to coarse sand with increasing pebble clasts up to 1.20 m thick (facies Sh). Faintly ripple-laminated medium sand, rich in chalk granules, interbedded with grey silt drapes 2–3 cm thick, the overall unit being 1.35 m thick (facies Sr) overlies the previous sediments. This bed is truncated by a marked horizontal erosional surface overlain by fine to medium matrix-supported gravel. The gravels are not only dominated by chalk clasts of up to 15 cm in diameter, but also include flint, quartz, quartzite and occasional other lithologies (facies Gms). Gently dipping medium to coarse gravel foreset-bedded units of c. 0.40–1.20 m in thickness occurs at neighbouring sites. The large-scale foreset beds are divided by buff medium sand and interbedded silt laminae 1.5–2 cm thick. Palaeocurrent measurements indicate variable flow towards 105–180°, that is, towards the SE. Coarse gravel can only be seen close to the surface, 50 m N and NW of the exposure described. This sediment facies distribution parallels that found at other nearby sites, for example, Three Hills (Gibbard et al., Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009). To the SE of Maidscross Hill, the succession comprises laminated sands and silts at the base, resting on highly fragmented Chalk. Horizontally and ripple-cross-laminated sands are truncated by planar cross-stratified medium to fine gravel. The succession coarsens upwards again implying derivation from a source to the NW of the sample site.

Comparison of the facies successions recorded from the limited exposure conforms to the facies typical of mid- to distal slope facies (cf. Lang et al., Reference Lang, Le Heron, Van den Berg and Winsemann2021) with the sand-silt-dominated units reflecting cyclic step deposits, whilst the gravel units represent a higher energy proximal facies.

Three samples were collected for luminescence dating (Fig. 4). Two samples (Shfd18077 and Shfd18078) were taken from low in the stratigraphy from the horizontally stratified medium sand (Sh) unit. One sample (Shfd18079) was collected from a sand facies in the upper part of the fine to medium matrix-supported gravel.

Shouldham Thorpe, Norfolk

An exposure was cleaned and re-examined at the Parish pit located ∼1.5 km west of the village of Shouldham (National Grid Reference: TF 657085). This succession was first described by Lewis (Reference Lewis and Keen1989, Reference Lewis, Rose, Lewis, Whiteman and Bridgland1991) and was re-examined by Gibbard et al. (Reference Gibbard, West, Boreham and Rolfe2012b). The profile comprises over 7 m of predominantly horizontally stratified deposits underlying the modern ground surface (Fig. 5). The basal sediments rest on bedrock, comprise matrix-supported fine to medium gravel (facies Gms) 30 cm thick and 20 cm of planar-parallel-bedded sand and are overlain by 4 m of horizontal multi-storey planar-parallel-bedded sand units, 30–40 cm thick (facies St, Sp), some units including a thin basal gravel lag. Horizontally stratified fine to medium, matrix-supported gravel (facies Gms) units of 10–25 cm thick occur resting on erosional bases. A shallow channel, 25 cm deep and 2.5 m wide, cut across the planar-parallel bedded sands, the base at 3.5 m depth, and was infilled by planar-parallel-bedded pebbly sand (facies Sh). A similar channel-like infill occurred slightly higher in the succession at 2.75 m depth.

Figure 5. Luminescence sample localities for the Shouldham Thorpe site with the approximate positions of IRSL samples and pIRIR225 ages shown on the composite stratigraphic log of Gibbard et al (Reference Gibbard, West, Boreham and Rolfe2012b).

The upper c. 1m of well-sorted medium sand with scattered pebbles, mostly of flint, blankets the succession (facies Scr), immediately beneath the modern ground surface (Fig. 5). The slightly reddened character of this deposit possibly represents a disrupted relict palaeosol, comparable to that seen at Tottenhill (Lewis and Rose, Reference Lewis, Rose, Lewis, Whiteman and Bridgland1991; Gibbard et al., Reference Gibbard, West, Andrew and Pettit1992). At the extreme N side of the exposure 20 cm below the ground surface, a tongue-like wedge of brown glacial diamicton (facies Dmm), 40 cm thick, rested on the underlying silts with a sharp basal boundary. Throughout the deposits, palaeocurrent measurements indicate a consistent flow direction towards SE-SSE, as noted by Lewis (Reference Lewis and Keen1989; Reference Lewis, Rose, Lewis, Whiteman and Bridgland1991).

Examination of the internal structure and form of the feature, including GPR, supported by section logging, borehole records, local landscape morphology and previous description, together indicate that the deposits rest on an eroded surface of Lowestoft Formation diamicton (Anglian Stage) and are therefore of post-Anglian age (Gibbard et al., Reference Gibbard, West, Boreham and Rolfe2012b). The investigations indicate that the Shouldham deposits were laid down as a subaerial glaciomarginal fan directly in contact with the ice front.

Three samples were collected for luminescence dating (Fig. 5). One (Shfd18081) was from low in the stratigraphy in the planar-parallel-bedded sand (Sp) unit. The second (Shfd18082) was collected from mid-way up the stratigraphic profile in planar cross-bedded sand (Sp). The third (Shfd18080) was from the upper part of the succession in horizontally bedded sand immediately below the diamicton.

Watlington Quarry

Present-day quarrying provided an opportunity to view sediments between the villages of Watlington and Tottenhill (National Grid Reference: TF 625109). A recently exposed working quarry face revealed a ∼60 m long, 4 m high vertical face approximately 7 m OD in elevation (Fig. 6).

Figure 6. Composite log with Luminescence sample localities and pIRIR225 ages for the Watlington Site. Note vertically aligned clasts adjacent to sand filled cryoturbation feature.

Logging revealed the exposure to be mostly poorly bedded to massive matrix-supported fine to medium gravel (Gms). The gravel comprised almost entirely of flint (97%) and the matrix was a medium to coarse sand. In places it was noted in situ clasts had been split. Borehole logs indicate a further 18 m of gravel beneath the exposure sitting on Jurassic Kimmeridge Formation clay. Within the gravel were large teardrop shaped periglacial cryoturbation structures ranging from 1.4 to 2.5 m in width and 1.6 to 2.7 m in depth (Fig. 7). These clearly had developed after gravel deposition as the boundaries were sharp and clast orientation in gravel directly adjacent to the structures showed preferential vertical alignment. The cryoturbation structures were filled with sand (Ss) and occasional clasts with some evidence of fining away from the centre of the feature as the margins were more clayey. In places, the sand was indurated and there was clear evidence for post-depositional iron staining with a well-developed iron pan at the base of each feature. Planform excavations during quarrying revealed these features are irregularly spaced and not forming a network (Fig. 7d and e).

Figure 7. Cryoturbation structures found at Watlington Quarry. (A) vertical profile through structures which repeat and Irregular Intervals with (B) annotated version showing feature boundaries. (C) planform of cryoturbation structure with (D) vertical profile through same structure. (E) cleared quarry floor showing frequency of structures within a ∼50 m2 area (photograph courtesy of Vince Spall) with (F) annotated version showing feature boundaries.

The gravels revealed at Watlington are thought to form part of a gravel train (the Watlington Member) which was identified by Gibbard et al. (Reference Gibbard, West and Hughes2018). This extends along the eastern Fenland margin northwards from north of Downham Market to Watlington, immediately west of Tottenhill, at the mouth of the Nar Valley (Figs. 1 and 2). The deposits’ surface forms a distinct terrace-like feature declining in the same direction from c. 9 m O.D. to 5 m O.D. at Watlington, its present form including a steep west-facing margin, whilst its eastern limit forms a gentle gradient with local topography. At its northern end, the spread abuts the Tottenhill deposits described by Gibbard et al. (Reference Gibbard, West, Andrew, Pettit, Lewis, Whiteman and Bridgland1991; Reference Gibbard, West, Andrew and Pettit1992), the uppermost surface of which occurs at 12 m O.D. However, since the terraciform surface of the Watlington Gravel deposits occurs at a distinctly lower elevation (c. 5–6 m O.D.), Gibbard et al. (Reference Gibbard, West and Hughes2018) concluded that it was incised into the deltaic accumulation subsequent to deposition of the latter.

Gallois (Reference Gallois1978) interpreted this spread as a fan deposited into a lake filling the Fenland basin. However, the form and occurrence of these deposits imply that they represent abraided stream, kame terrace accumulation laid down by meltwater flowing northwards marginal to the ice lobe during its occupation of the basin immediately to the west (Gibbard et al., Reference Gibbard, West and Hughes2018). The altitudinal relationship of this landform to the Tottenhill sequence demonstrates that the Watlington Gravel post-dates the former implying that it accumulated during a stillstand of the Fenland ice lobe when the meltwater drainage was aligned northwards towards the North Sea. This contrasts with the eastwards drainage that occurred during the phase represented by the glacial lacustrine deposits at Tottenhill itself.

A total for four samples were collected for luminescence dating from the Watlington Quarry. Two samples (Shfd19160 and Shfd19163) were collected from rare small (∼10 cm thick, ∼30 cm in length) sand lenses within the gravel (Fig 6). A further two samples (Shfd19161 and Shfd19162) were collected from the sand contained within two different cryoturbation features (Fig 6).

Sediment sampling and investigation

Field Methods

Locations for luminescence dating were selected in sand units devoid of organic material at least below 50 cm from the present-day surface to avoid recent pedoturbation or soil formation. At freshly cleaned locations, sand samples were obtained by driving 50 mm diameter opaque PVC tubes into the selected sediment. In situ dose rate measurements were also undertaken using an EG and G micronomad. Additional large (>20 kg) samples were taken at the Watlington Quarry site of the gravel and finer grained units for particle size, shape and roundness characterisation to aid interpretation of their transportation and depositional environment.

Sediment characterisation

The gravel and sand samples were dried and sieved through a nest of sieves using a mechanical agitator as Gale and Hoare (Reference Gale and Hoare2012). Particles <1 mm were measured using a Horiba LA-950 laser diffraction particle size distribution analyser. Prior to measurement, subsamples were riffled down and treated with 0.1% hexametaphosphate, before dispersal in de-ionised water within the instrument using ultrasound and pumping. Resultant data were used in GRADISTAv8 to calculate the mean grain size of each sample, sorting, skewness and kurtosis. Clasts >16 mm were also analysed for form and sphericity (ψP) per Gale and Hoare (Reference Gale and Hoare2012) and roundness/angularity as per Powers (1952).

Luminescence dating

Luminescence dating using OSL on extracted quartz minerals has been successfully applied to East Anglian sediments as old as MIS 12 (e.g. Pawley et al., Reference Pawley, Bailey, Rose, Moorlock, Hamblin, Booth and Lee2008 who measured ages back to 494 ± 42 ka). However, OSL dating as early as this is only possible where background dose rates are extremely low as they are on the Cretaceous Chalk. In areas with average background radioactivity, the quartz OSL signal saturates after 150,000 years of burial or younger (Mahan and DeWitt, Reference Mahan, DeWitt and Bateman2019). An alternative approach is to measure feldspars using infrared stimulated luminescence (IRSL) for which under average dose rate conditions an upper dating limit of 200,000–300,000 years or even more has been reported (Mahan and DeWitt, Reference Mahan, DeWitt and Bateman2019). Unfortunately, IRSL signal measured at 50°C (IRSL50) has been shown to sometime underestimate ages due to anomalous fading (Spooner, Reference Spooner1994; Mahan and DeWitt, Reference Mahan, DeWitt and Bateman2019) leading the necessity for complex and very precise fading corrections being needed (e.g. Lamothe et al., Reference Lamothe, Auclair, Hamzaoui and Huot2003). However, more recently it has been found that fading problems can be eliminated or significantly reduced by measuring the IRSL signal at an elevated temperature after the IRSL50 signal has been measured (e.g. Buylaert et al., Reference Buylaert, Murray, Thomsen and Jain2009).

As outlined by Bateman (Reference Bateman2019), the other significant challenge for the successful application of luminescence dating to glacial, periglacial and fluvial sediments is that prior to burial sediments were exposed to sufficient sunlight (bleached) at some point during erosion, transportation and at deposition. From this perspective, OSL signal resets quicker than IRSL50 and IRSL signal measured at 225°C (IRSL225) is even slower to reset (Bateman, Reference Bateman2019, Fig 8.2). A strategy employed to help with this is making multiple replicate measurements of palaeodoses (De). A well-bleached sediment should have a tight normally distributed De distribution centred on the true burial age and a low over-dispersion (OD). In contrast where only some grains were bleached, a skewed or multimodal De distribution would be expected with high OD (Bateman, Reference Bateman2019, Fig 8.5).

Given the potential antiquity of the collected samples and the discussion above, both IRSL50 and IRSL at 225ºC (IRSL225) measurements from extracted feldspars were employed in this study as per Bickel et al. (Reference Bickel, Lüthgens, Lomax and Fiebig2015). Samples were prepared following the procedure outlined in Bateman and Catt (Reference Bateman and Catt1996) using a grain size range of 180–212µm. Prepared feldspar grains were mounted as a ∼5-mm diameter monolayer on 9.6-mm diameter stainless steel discs. Each aliquot therefore comprised ∼650 grains. All measurements were undertaken following a preheat of 260°C for 300 seconds in a Risø luminescence reader with stimulation from IR LEDs. Palaeodoses (De) were measured using the single aliquot regenerative (SAR) approach of Murray and Wintle (Reference Murray and Wintle2003) with five regeneration points. As per Rhodes (Reference Rhodes2015) following IRSL measurement at 50°C (IRSL50), the IRSL signal was measured a second time with the sample held to 225°C. This is referred to as the post-IRSL IRSL signal (pIRIR225). Sensitivity corrections were made from repeat measurement of an experimentally derived 50 Gy test dose, and a thermal bleach at 290oc was employed at the end of each SAR cycle to ensure that all traps were emptied before the next SAR cycle. At least 24 replicates of each sample were measured.

All IRSL measurements showed a strong rapidly decreasing signal (Fig. 8A and B) and growth curves which grew well with laboratory doses (Fig. 8C and D). For samples from Watlington and Maidscross Hill, SAR regeneration dose points showed a good fit with a single saturating exponential curve. Importantly, all aliquots from these samples had growth curves that showed no signs of saturation (as exemplified in Fig. 8E). SAR growth curve data from the Shouldham samples were best fitted with expontential + linear curves as the De values for this site were much higher (>375 Gy). Two samples (Shfd18080 and Shfd18081) from this site had 20% and 8%, respectively, of saturated aliquots. When replicates were examined for each sample, all had normal distributions with low OD and limited skewness with no indication of incomplete bleaching.

Figure 8. Example IRSL data from sample Shfd18077. (A) and (B) Shine down curves showing rapid trap emptying with IRSL50 and IRSL225 stimulation. (C) and (D) SAR growth curves of the same aliquot measured with IRSL50 (C) and IRSL225 (D). Note where red line intersects the X axis showing a higher recovered Dose for the IRSL225 measurement. (E) SAR growth curve measured with IRSL50 showing a saturated aliquot where the natural dose plotted on the Y axis does not intersect the SAR growth curve. (F) SAR growth curve measured with IRSL50 showing an aliquot best fitted by a single saturating exponential + linear curve to obtain a De value.

External dose rates for the samples were based on the field gamma spectrometry measurements for the gamma dose. External beta dose rates were based on Inductively coupled plasma - optical emission spectrometry (ICP-OES) and Inductively coupled plasma mass spectrometry (ICP-MS) elemental measurements converted dose rates using data from Guerin et al. (Reference Guerin, Mercier and Adamiec2011). Both beta and gamma doses were appropriately attenuated for grain size, density and a palaeomoisture value based on present-day moisture levels (Table 2). The latter was assumed as whilst the sediments would have been saturated at deposition and during the establishment of permafrost during MIS 2, the present-day values are thought to represent the majority of time as the sampled sediments are free draining sands and gravels. The exception to this was the Watlington quarry which is at a lower elevation, overlying clay and which currently has to be pumped. Sediment here may have been saturated for longer. For this site, a partially saturated palaeomoisture value of 15% (as per Evans et al., Reference Evans, Robert, Bateman, Clark, Medialdea, Callard, Grimoldi, Chiverrell, Ely, Dove, Ó Cofaigh, Saher, Bradwell, Moreton, Fabel and Bradley2021) was applied. A 5% error was applied to this term to incorporate fluctuations through time. An internal dose rate was based on an assumed internal potassium content of 12% (as Huntley and Baril, Reference Huntley and Baril1997) and Rb of 400 ppm (as per Huntley and Hancock, Reference Huntley and Hancock2001). The Prescott and Hutton (Reference Prescott and Hutton1994) algorithm was used to calculate the cosmogenic-derived dose rate. Ages were calculated from 2020. Given the good replicate reproducibility, limited De replicate skew and low OD values, De values for each sample were extracted using the Common Age Model of Galbriath and Green (Reference Galbraith and Green1990). De values for measurements at pIRIR225 also include a subtraction of a residual of 10.73 Gy as determined on Shfd18077 by prolonged daylight bleaching (7 days) in the University of Sheffield, followed by measurement as above.

Table 2. Luminescence related data for sampled sites.

a Dose rate determined from ICP-MS elemental concentrations with an assumed internal K concentration of 12%.

b Dose rate determined by in situ gamma spectroscopy.

c Number of accepted aliquots.

d Ages presented in years from the year 2020 with 1 sigma uncertainties.

e An experimentally determined residual of 10.73 Gy was subtracted from the measured De to obtain the value presented.

Results

Sediment characterisation

Results from Watlington show that 69% of clasts are sub-angular to very angular (Fig. 9). Whilst flints tend to be angular and are resistant to wear having as they do a low abrasional response (Sneed and Folk, Reference Sneed and Folk1958), it may also indicate the majority of clasts were only transported a relatively short distance. The small percentage of ‘rounded’ flint are interpreted as reworked clasts (Eyles et al., Reference Eyles, Eyles and Miall1983). Particle size analysis of the gravel unit showed it to have a 78:22 ratio of gravel to sand and a mean size of 11–16 mm being best described as a very poorly sorted sandy medium gravel (Fig. 10). Bladed- and platy-shaped clasts make up to 69% of the gravel with sphericity analysis showing no dominant categories. Based on the covariance of C40 and RA indices and RA and RWS indices (cf. Benn and Ballantyne, Reference Benn and Ballantyne1994 for details), the gravels fall into the subglacial envelopes (Table 2; Lukas et al., Reference Lukas, Benn, Boston, Brook, Coray, Evans, Graf, Kellerer-Pirklbauer, Kirkbride, Krabbendam and Lovell2013). In summary, it would appear that the majority of the clasts were only transported a relatively short distance by ice.

Figure 9. Sediment characterisation of the Watlington Gravels (A) Shape (B) Roundness/Angularity (C) Particle size distribution of Watlington Gravels.

Figure 10. Roundness indices applied to the Watlington Gravels indicating (as per Lukas et al Reference Lukas, Benn, Boston, Brook, Coray, Evans, Graf, Kellerer-Pirklbauer, Kirkbride, Krabbendam and Lovell2013) a sub-glacial origin. (A) the C40/RA covariance where the RA index for roundness is calculated as the percentage of angular and very angular clast in a sample (B) the C40/RWR covariance where RWR index is calculated as the percentage of rounded and well-rounded clast in the same sample.

The cryoturbation structures are interpreted as either thermokarst or flat-bottomed involutions, the bases of which indicate an active layer of at least 2.5 m when they were forming resulting from liquefaction (load casting) of sediments in a very wet environment. They are similar in size, shape and connectivity to those described from Belgium by Gullentops and Paulissen (Reference Gullentops and Paulissen1978). The numerous in situ broken clasts that found throughout the gravel unit are interpreted as indicating intense freeze/thaw processes either just after gravel deposition or during subsequent periglacial phases. The involution fill is unimodal and best described as a moderately sorted gravelly sand, dominated by sand in the 250–350 µm size range.

Luminescence ages

As can be seen in Table 2, whilst the IR50 De measurements are consistent with each other, they are much smaller than their equivalent pIRIR225 De values even when the residual has been subtracted from the latter. Given both the IR50 and pIRIR225 De distributions are broadly similar in shape (Fig. 9), it is thought less likely that the younger IR50 ages represent better resetting prior to burial. Instead it is thought the lower ages represent the impacts of uncorrected for anomalous fading. No fading correction was made on the pIRIR225 measurements as studies have shown natural (as opposed to laboratory-induced) fading at elevated temperatures is reduced or not observable (e.g. Rhodes Reference Rhodes2015). On this basis, the pIRIR225 ages are preferred and used in the discussion that follows.

The uppermost sample (Shfd18079) at Maidcross Hill has an age of 14.4 ± 0.6 ka indicating MIS 2 deposition at the site, associated with periglacial cryoturbation and aeolian activity as seen nearby (Bateman et al. Reference Bateman, Hitchens, Murton, Lee and Gibbard2014). The other samples from low down in the stratigraphy are much older at 96 ± 4 ka (Shfd18078) and 169 ± 6 ka (Shfd18077). The former is disregarded as despite being lower in the succession, it returns a younger age. As the sample was collected in a test pit dug in the quarry floor, it is presumed to have suffered from anthropogenic disturbance during past quarrying of the site. The best age estimate for the Maidscross Hill deltaic gravels is therefore ∼163–175 ka (MIS 6c).

Ages from Shouldham Thorpe conform to stratigraphic depth and are 211 ± 8 ka (Shfd18080), 212 ± 9 ka (Shfd18082) and 244 ± 10 ka (Shfd18081). Taken at face value, the sediments at this site appear to have been emplaced during MIS 7 or the very start of MIS 6 (i.e. Late Wolstonian Substage) at the latest. However, whilst closer examination of the pIRIR data showed no indication of partial bleaching of the aliquot De replicates, it did reveal samples Shfd18080 and Shf18081 had saturated aliquots and all samples had large De values and required fitting with expontential + linear growth curves. Therefore, it cannot be completely ruled out that these may be saturated ages as the samples appear to be at the limit of the luminescence measurements employed.

At Watlington, the extensive gravel unit yielded ages of 148 ± 6 ka and 192 ± 5 ka (Shfd19160 and Shfd19163). Subsequent to this intense and severe periglacial activity took place during MIS 2 (i.e. the Late Devensian Substage) based on the ages from the involutions which were 26.1 ± 1.0 ka and 25.9 ± 1.3 ka. These coincide with a time when the last British and Irish Ice sheet was approaching the present Norfolk coast ∼30 km to the north (Evans et al Reference Evans, Roberts, Bateman, Ely, Medialdea, Burke, Chiverall, Clark and Fabel2019). The best age estimate for the Watlington Member gravels is therefore ∼148–192 ka (i.e. MIS 6, Late Wolstonian Substage).

Synthesis

Numerical age dating

As already stated, the aim of this project was to examine whether previously published attributions of the Tottenhill glacial advance and the Skertchly Line to MIS 6 (∼160 ka, i.e. Late Wolstonian Substage) could be geochronologically substantiated. Ages from Shouldham are older than MIS 6. Whilst no evidence was seen in the luminescence data of partial bleaching, the sediments sampled are thought to have only been a maximum of 30–50 m from the Tottenhill glacial ice front and were deposited in a shallow channel eroded into the Lowestoft diamicton. This raises the possibility that the sediments were moved subglacially (possibly not very far) and laid down under turbid water thereby precluding any bleaching of the pIRIR signal (e.g. Livingstone et al., 2015; Bateman et al., Reference Bateman, Swift, Piotrowski, Rhodes and Damsgaard2018). If this was the case, then the ages from Shouldham are maximum ages for the Tottenhill glacial advance and possibly provide numerical ages of the pre-existing sediment from which they were reworked. Future work using pIRIR at multiple elevated temperatures (e.g. Bateman et al., Reference Bateman, Kinnaird, Hill, Ashurst, Mohan, Bateman and Robinson2021) to access signal of varying bleachability and at the single grain level would be able to better understand whether partial bleaching or no bleaching is an issue in such ice-proximal settings. In doing this, careful evaluation of saturation limits may be required for some samples. In contrast, the new dating results from both Maidcross Hill and Watlington are coincident with each other, show no problems with saturating signal and clearly support a MIS 6 age for the Tottenhill glacial advance.

In light of these new ages, a re-examination is needed of previously reported evidence relevant to the Tottenhill glaciation and why, in some instances, a MIS 8 or older age has been ascribed to it. In support of an MIS 6 attribution, a sample from the Tottenhill Sands and Gravels Member gave an OSL quartz age of c. 160 ka (S. Pawley, Reference Pawley2006; personal communication) as did a preliminary determination by E. Rhodes (personal communication) from the sands at the Warren Hill (Three Hills). Looking further afield at other glacially related sediments, two OSL dates from the glaciolacustrine Plantation Sands (Lewis, Reference Lewis, Boismier, Gamble and Coward2012; Gibbard et al., Reference Gibbard, West and Hughes2018) at Lynford, Suffolk, in the Wissey valley gave ages of 169 ± 26.9 ka and 176 ± 27.7 ka (Schwenninger and Rhodes, Reference Schwenninger and Rhodes2012, pp. 30, 68). Additionally, the ages from the Stiffkey moraine on the north Norfolk coast dated this to 141 ± 9.4 and 165 ± 11 ka by Evans et al. (Reference Evans, Roberts, Bateman, Ely, Medialdea, Burke, Chiverall, Clark and Fabel2019). Taken together, these ages strongly suggest the Tottenhill ice advance was of MIS 6 in age.

Although some authors suggested that the Tottenhill glaciation might be of Middle Wolstonian (c. MIS 8 or 10) age, such a correlation was, however, based on OSL ages reported by Straw (Reference Straw2000, Reference Straw2005, Reference Straw2011) and White et al. (Reference White, Bridgland, Westaway, Howard and White2010, Reference White, Bridgland, Westaway and Straw2017) from Lincolnshire and the Trent valley system ∼90 km further north-west. This association has been previously rejected by Schwenninger et al. (Reference Schenninger, Bridgland, Howard and White2007a/b, p.65) who described these OSL ages as ‘inaccurately determined’ and that ‘only dates from deposits younger than the Ipswichian are credible’. Elsewhere, glaciations that may have occurred early during the Wolstonian Stage (?MIS 8–10) have been previously suggested (cf. Clark et al. Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004). These were based principally on geochronometry of overlying or underlying non-glacial deposits and long-distance comparison with the Thames’ system deposits in the south English Midlands. The evidence central to the interpretation was that obtained from U-series determinations from the Nar Valley, near Kings Lynn in Norfolk. Here, the glaciolacustrine Setch Clays (part of the Nar Valley Clays) overlie Lowestoft Formation till and are, in turn, overlain by ice-contact glaciodeltaic Tottenhill Member sands and gravels. A freshwater peat underlying the Setch Clay yielded an age of 317 ± 14 ka (Rowe et al., Reference Rowe, Richards, Atkinson, Bottrell and Cliff1997), which Rose (in Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004), following Scourse et al. (Reference Scourse, Austin, Sejrup and Ansari1999), interpreted as implying that the underlying till was deposited during MIS 10. The most frequently quoted example of pre-MIS 6 late Middle Pleistocene glaciation is that reported by Beets et al. (Reference Beets, Meijer, Beets, Cleveringa, Laban and van der Spek2005) suggesting that pre-Late Saalian (i.e. Middle Saalian; MIS 8) till occurs in the North Sea basin based on geophysical, micropalaeontological and amino-acid age evidence. While there is no question that till occurs at the site, there remains scepticism about the age attribution among Dutch workers who generally attribute these deposits to the Late Saalian (MIS 6; Cohen, K.M., personal communication, 2017). Despite other possible MIS 8 records from other circum – North Sea localities (e.g. White et al., Reference White, Bridgland, Westaway, Howard and White2010, Reference White, Bridgland, Westaway and Straw2017; Davies et al., Reference Davies, Roberts, Bridgland, Ó Cofaigh, Riding, Demarchi, Penkman and Pawley2012; Bridgland et al., Reference Bridgland, Howard, White, White and Westaway2015; Roskosch et al., Reference Roskosch, Winsemann, Polom, Brandes, Tsukamoto, Weitkamp, Bartholomäus, Henningsen and Frechen2015), all of these remain equally equivocal. Nowhere else in eastern England, nor the adjacent North Sea basin, has a diamicton of this age been identified and it this conflicts with both the litho- and biostratigraphy at Tottenhill (cf. Ventris, Reference Ventris1985, Reference Ventris, West and Whiteman1986, Reference Ventris1996), as well as with the regional stratigraphy (Gibbard et al., Reference Gibbard, West, Andrew and Pettit1992; Gibbard, in Clark et al., Reference Clark, Gibbard, Rose, Ehlers and Gibbard2004). Recent, amino-acid racemisation results from shells found in the Nar Valley Freshwater Beds indicate a MIS 9 and MIS 11 deposition (Barlow et al., Reference Barlow, Long, Gehrels, Saher, Scaife, Davies, Penkman, Bridgland, Sparkes, Smart and Taylor2017), making the underlying till more likely to relate to MIS 12. The unconformably overlying Tottenhill sands and gravels by implication therefore must post-date MIS 9, so they do not contradict the above new chronological attribution of them to MIS 6.

Elsewhere in East Anglia dating of samples collected from what are presumed to be the ice-contact (glaciomarginal) deltaic deposits at Warren Hill (i.e. Three Hills) and Maidscross Hill, that is, the Three Hills and Maidscross member, have been reported by Voinchet et al. (Reference Voinchet, Moreno, Bahain, Tissoux, Tombret, Falguères, Moncel, Schreve, Candy, Antoine and Ashton2015). These samples were dated by the electron spin resonance (ESR) method and produced ages of 544 ± 53 ka and 539 ± 38 ka, and 529 ± 55 and 631 ± 56 ka, respectively, which these authors conclude indicates the sediments being deposited during the early Middle Pleistocene. The deposits they dated, however, include significant quantities of chalk clasts (unlike those in the present study), which have demonstrably undergone post-depositional solution, thereby making it likely that the dose rate used for the ESR ages through time has changed. Additionally, since these sediments were deposited in an immediate ice-contact position with the Tottenhill ice lobe (as at Shouldham in this study) and the ESR signals used are harder to reset than those of OSL or IRSL, age over-estimation is possible due to the presence of an unreset antecedent signal at burial. It may be therefore that the dates obtained, rather than reflecting the ice-contact deltaic depositional event represented by the Skertchly Line sequences, instead indicate the age of the source deposits from which the materials were reworked by the Tottenhill ice lobe.

Regional implications

A MIS 6 (∼160 ka) Tottenhill glacial advance reinforces the view previously presented that during the Late Wolstonian Substage (the Drenthe Stadial: Table 1), a substantial ice lobe advanced down the eastern side of Britain entered the Fenland and fanned outwards broadly towards the east, south-east, south and west (Figs. 3, 11). The advancing ice apparently stalling against the rising ground was underlain by the more resistant bedrock and was halted by the rising ground of the chalk hills to the east and south Chalk on the East Fenland margin. Deposition of these ice-contact delta fans (the Skertchly Line), which prograded into ice-dammed lake or lakes in direct contact with the ice lobe (Gibbard et al., Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009; Reference Gibbard, West and Hughes2018), arose from damming of the local streams, such as the Lark and Little Ouse. Initially, the lakes formed in each valley, but subsequently coalesed as the water level rose to form the extensive Lake Paterson in the south and south-eastern Fenland marginal zone. Similar lakes formed in the Nar and Wissey valleys. At Shouldham Thorpe above the lake level, a subaerial ice-contact fan was formed.

Figure 11. Postulated maximum limit of the Wolstonian Tottenhill and equivalent Drenthe glacial lobes in the southern North Sea basin. Modified from Gibson (Reference Gibson2018) and Gibbard et al Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009).

As Gibbard et al. (Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009; Reference Gibbard, West and Hughes2018) have demonstrated, after reaching its maximum extent, the ice began to retreat in an oscillatory fashion, the dynamic ice front alternating stillstands or minor re-advances that punctuated the general ice lobe retreat. During this period the Watlington Member gravel spread, on the north-eastern Fenland margin, northwards flowing meltwater marginal to the Tottenhill ice lobe apparently formed as a kame terrace-like deposit. This glaciofluvial unit, abutting the Tottenhill delta, demonstrably post-dates the latter. This indicates the kame terrace almost certainly accumulated during a stillstand phase in the local ice recession when drainage was aligned northwards towards the North Sea via the Wash gap, contrasting with the eastwards drainage that occurred during the maximum phase represented by the glacio-lacustrine deposits at Tottenhill and other Skertchly Line localities.

Severe periglaciation during the latest Wolstonian time and through the Devensian Stage is represented by the substantial ice wedge casts and associated cryogenic structures at Watlington. A further significant development during the Devensian was the wide dispersal and deposition of aeolian coversand, most recently during the Late Devensian Substage (∼MIS 2), largely originating from recycling of the distal-deltaic sand beds of the Wolstonian glacial lake deposits over the landscape, giving the character of the Breckland of East Anglia (Bateman et al., Reference Bateman, Hitchens, Murton, Lee and Gibbard2014), and represented in the uppermost deposits at Watlington, Shouldham Thorpe and Three Hills (Warren Hill).

An equivalent to the substantial glaciation in eastern England during the Wolstonian Stage has been recognised by Shotton (Reference Shotton1953, etc.) and Rice (Reference Rice1968, etc.) in the adjacent English Midlands. Bridgland et al. (Reference Bridgland, Howard, White, White and Westaway2015) and White et al. (Reference White, Bridgland, Westaway, Howard and White2010) noted a potentially equivalent glaciation during investigations of River Trent terrace deposits in adjacent western Lincolnshire and Nottinghamshire. However, these authors followed Straw (Reference Straw2000, Reference Straw2005, Reference Straw2011) in favouring an older age for the glaciation, which they equated to MIS 8 (i.e. Middle Wolstonian Substage: Fig. 1b) rather than MIS 6, an attribution based on the landscape relationships in the Lincolnshire district. Straw (Reference Straw2000, Reference Straw2005, Reference Straw2011) also based his correlation of the glaciation with MIS 8 by comparison with the near Continent, where he considered the substantial glacial event, the classical Saalian Glaciation, also occurred during that stage. Unfortunately, Straw’s (Reference Straw2000, Reference Straw2005, Reference Straw2011) assumption is not supported by continental workers, the Late Saalian (Drenthe Stadial) Glaciation having been repeatedly equated with MIS 6 throughout northern Europe (e.g. Zagwijn, Reference Zagwijn1973; Busschers et al., Reference Busschers, van Balen, Cohen, Kasse, Weerts, Wallinga and Bunnik2008; Toucanne et al., Reference Toucanne, Zaragosi, Bourillet, Cremer, Eynaud, Van Vliet-Lanoe, Penaud, Fontanier, Turon, Cortijo and Gibbard2009; Ehlers, Reference Ehlers2011; Roskosch et al., Reference Roskosch, Winsemann, Polom, Brandes, Tsukamoto, Weitkamp, Bartholomäus, Henningsen and Frechen2015; Lang et al., Reference Lang, Lauer and Winsemann2018). Nevertheless, Straw (Reference Straw2005, p.34) was aware of the weakness of his case, conceding that his Lincolnshire, Welton glaciation ‘could fall into any of the [MIS] Stages 6, 8 or 10’ (e.g. White et al., Reference White, Bridgland, Westaway and Straw2017). The dating evidence in the River Trent successions is also disputed (cf. Gibbard et al., Reference Gibbard, Peglar and West2021). Therefore, while it remains possible that an earlier glaciation could conceivably have occurred in Lincolnshire within the Wolstonian Stage, there is a greater probability that the event identified by these authors is the northern equivalent of the Tottenhill glaciation, described here, the dating of which was tested during the current studies.

As Gibbard et al. (Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011) and Clark and Gibbard (Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011) demonstrate, the age attribution to MIS 6 is further reinforced in the southern North Sea basin (Fig. 11). Here detailed analysis of offshore geophysical evidence indicates that the ‘Skertchly Line’ glacial limit can be traced north of East Anglia (the Norfolk High), based on the extent of tunnel valleys, marginal ice-contact delta-fan accumulations closely similar to those on-land and push moraine ridge structures. Where this limit reaches the North Sea Centre Line, it continues directly as the Netherlands’ Drenthe Stadial glaciation maximum (Moreau et al., Reference Moreau, Huuse, Gibbard and Moscariello2009; Moreau, Reference Moreau2010; Clark and Gibbard, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011, Gibbard et al., Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Gibbard, West, Boreham and Rolfe2012a, b). The detailed seismic analysis clearly differentiates this strongly defined feature from those of the earlier and later glaciation limits. The identification of the Tottenhill/Drenthe line confirms that the glacial maximum identified in the Fenland region by Gibbard et al. (Reference Gibbard, West, Andrew and Pettit1992, Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011, Reference Gibbard, West and Hughes2018) is indeed the continuation of the southernmost limit of the Drenthe Stadial glaciation in the Netherlands (Amersfoort–Nijmegen glaciotectonic ridge) (Laban and van der Meer, Reference Laban, van der Meer, Ehlers and Gibbard2004; Busschers et al., Reference Busschers, Kasse, Van Balen, Vandenberghe, Cohen, Weerts, Wallinga, Johns, Cleveringa and Bunnik2007, Reference Busschers, van Balen, Cohen, Kasse, Weerts, Wallinga and Bunnik2008; Kars et al., Reference Kars, Busschers and Wallinga2012), the British and Scandinavian ice lobes being confluent, and further east in western Germany (e.g. Lang et al., Reference Lang, Lauer and Winsemann2018). It must therefore represent the same interval, that is, c. 180–160 ka, as Gibbard et al. (Reference Gibbard, West, Andrew and Pettit1992; Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009; Reference Gibbard, West and Hughes2018) and Clark and Gibbard (Reference Clark, Gibbard, Ehlers, Gibbard and Hughes2011) concluded. Beyond the confluent British and Scandinavian ice sheets, a glacial lake was formed in the southern North Sea basin (cf. Busschers et al., Reference Busschers, Kasse, Van Balen, Vandenberghe, Cohen, Weerts, Wallinga, Johns, Cleveringa and Bunnik2007, Reference Busschers, van Balen, Cohen, Kasse, Weerts, Wallinga and Bunnik2008; Gibbard, Reference Gibbard2007; Cohen et al., Reference Cohen, Gibbard and Weerts2014; Ehlers, Reference Ehlers2011; Gibbard and Cohen, Reference Gibbard and Cohen2015), the overflow discharge from which it is recorded off the English Channel in the Bay of Biscay ocean floor sediments (Toucanne et al., Reference Toucanne, Zaragosi, Bourillet, Cremer, Eynaud, Van Vliet-Lanoe, Penaud, Fontanier, Turon, Cortijo and Gibbard2009). This evidence confirms the correlations shown in Table 1.

Conclusions

In order to test the previously established conclusions that the east Fenland margin glacial complexes and associated kame terrace-like deposits (Feltwell Formation) dated from the late Middle Pleistocene, a series of luminescence samples were collected from three significant localities in the Tottenhill glaciation Skertchly Line limit. The samples from Shouldham Thorpe and Maidscross Hill, Suffolk, were taken respectively from a subaerial glaciomarginal (ice-contact) alluvial fan and fan delta deposits, whilst those from Watlington, Norfolk, were collected from ice-marginal, subaerial kame terrace deposits.

Results firmly support the correlation of the Tottenhill glaciation with the Late Wolstonian Substage (MIS 6). The dates obtained correspond closely to those obtained from glaciofluvial deposits at Stiffkey on the Northwest Norfolk coast, those determined from the glaciolacustrine Plantation Sands (representing Lake Paterson) at Lynford, Suffolk, in the Wissey valley, together with unpublished determinations from Tottenhill and Three Hills (Warren Hill) previously noted by Gibbard et al. (Reference Gibbard, Pasanen, West, Lunkka, Boreham, Cohen and Rolfe2009, etc.). These ages conflict with the considerably older age determined from samples collected from deposits at Warren Hill (i.e. Three Hills) and Maidscross Hill, that is, the Three Hills and Maidscross members obtained by Voinchet et al. (Reference Voinchet, Moreno, Bahain, Tissoux, Tombret, Falguères, Moncel, Schreve, Candy, Antoine and Ashton2015) which are rejected as age over-estimates (see text for discussion). Likewise, U-series determinations from the late-Anglian age glaciolacustrine Setch Clays at Tottenhill, Norfolk, underlying the glaciodeltaic Tottenhill Member sands and gravels, which gave an MIS 9 age, have also been rejected.

Later formation of substantial permafrost structures, in particular ice wedge casts and cryoturbations at Watlington, together with widespread aeolian deposition of reworked glaciolacustrine sands, occurred under periglacial conditions, most recently during the Late Devensian Substage (∼MIS 2).

The new ages support the previous conclusions regarding the age of the maximum extent of the Late Wolstonian ice lobe in East Anglia (Table 1) and correspond closely to dating of the glacial maximum in the West Midlands type area (Gibson, Reference Gibson2018).

Comparison with the sequences and geochronology on the eastern side of the North Sea indicates that they correspond closely both in terms of the geology and their geochronology with the Tottenhill glaciation and indeed confirms that it is the direct equivalent of the Late Saalian Drenthe Stadial in the southern North Sea basin and on the adjacent Continent. Indeed the Skertchly Line glacial maximum limit appears to represent the direct continuation of the Amersfoort–Nijmegen glaciotectonic ridge limit in the central Netherlands. This conclusion demonstrates the nature and behaviour of the Late Wolstonian/Late Saalian ice margin across the southern North Sea region, the ice margin being characterised by multiple lobate oscillations giving rise to glaciotectonically ice-pushed ridge landforms and associated localised meltwater discharge landforms. In total, the nature of these landforms, together with their localised distribution suggest that the ice margin, at its maximum extent, was dynamically active and potentially unstable.

Future work should concentrate on carefully controlled numerical age dating of other localities in the region as they become available. Given the ice-proximal (glaciomarginal) nature of many of the sediments associated with the Skertchly Line and the apparent antiquity, future application of luminescence dating to them would benefit from avoiding chalk-rich deposits whose dose rate may have changed through burial due to dissolution. Also careful evaluation of how well the sediments are bleached should be undertaken both through measurement at the single grain level and using measurements made at multiple elevated temperatures to access signals with a range of bleachability (cf. Bateman et al. Reference Bateman, Kinnaird, Hill, Ashurst, Mohan, Bateman and Robinson2021). However, needless to say, the samples should be determined from profiles that are fully understood in regard to their genesis and relationship to local and regional sequences.

Acknowledgements

Access to Watlington quarry was with the kind permission of the staff of Frimstone Ltd. Rob Ashurst is thanked for his help with luminescence sample preparation. Rebecca Bateman and Tim Holt-Wilson are thanked for their assistance in the field when sampling. We are grateful to Philip Stickler (Department of Geography, University of Cambridge) for his patient drafting of some of the illustrations. PG thanks the Leverhulme Foundation (grant EM-2017-006) for financial support. The authors thank Professor Jutta Winsemann, Dr Freek Busschers, Dr Elizabeth Chamberlain and the NJG Associate Editor Dr Harm Jan Pierik for their reviews of this report.

Data availability

Data are available from the references cited and the public information cited in the text. The latter are from publications and website borehole archive of the British Geological Survey: www.bgs.ac.uk

Competing interests

There are no competing interests.

Authors’ contributions

All authors conceived, designed, analysed and interpreted the information presented; the drafting of the article or revising it critically for important intellectual content is the result of equal co-operation between the three authors. All authors gave final approval for publication.

Funding

PG thanks the Leverhulme Foundation for financial support.

Research ethics

No ethical assessment is required for conducting this research.

Animal ethics

No ethical assessment is required for conducting this research.

Permission to carry out fieldwork

The appropriate permissions to conduct the fieldwork were obtained from landowners and the Forestry Commission.

Footnotes

a

Deceased.

References

Ashton, N., Lewis, S.J., Parfitt, S.A., Penkman, K.E.H. & Coope, G.R., 2008. New evidence for complex climate change in MIS 11 from Hoxne, Suffolk, UK. Quaternary Science Reviews 27: 652668.CrossRefGoogle ScholarPubMed
Bateman, M.D., 2019. Handbook of luminescence dating. Whittles Publishing: 416 pp.Google Scholar
Barlow, N., Long, A.J., Gehrels, W.R., Saher, M.H., Scaife, R.G., Davies, H.J., Penkman, K.E.H., Bridgland, D.R., Sparkes, A., Smart, C.W. & Taylor, S., 2017. Relative sea-level variability during the late Middle Pleistocene: New evidence from eastern England. Quaternary Science Reviews 173: 2039.CrossRefGoogle Scholar
Bateman, M.D. & Catt, J.A., 1996. An absolute chronology for the raised beach and associated deposits at Sewerby, East Yorkshire, England. Journal of Quaternary Science 11: 389395.3.0.CO;2-K>CrossRefGoogle Scholar
Bateman, M.D., Hitchens, S., Murton, J.B., Lee, J.R. & Gibbard, P.L., 2014. The evolution of periglacial patterned ground in East Anglia, UK. Journal of Quaternary Science 29: 301317.CrossRefGoogle Scholar
Bateman, M.D., Swift, D.A., Piotrowski, J.A., Rhodes, E.J. & Damsgaard, A., 2018. Can glacial shearing of sediment reset the signal used for luminescence dating? Geomorphology 306: 90101.CrossRefGoogle Scholar
Bateman, M.D., Kinnaird, T.C., Hill, J., Ashurst, R.A., Mohan, J., Bateman, R.B.I. & Robinson, R., 2021. Detailing the impact of the Storegga tsunami at Montrose, Scotland. Boreas (in press).CrossRefGoogle Scholar
Benn, D.I. & Ballantyne, C.K., 1994. Reconstructing the transport history of glacigenic sediments: A new approach based on the co-variance of clast form indices. Sedimentary Geology 91: 215227.CrossRefGoogle Scholar
Beets, D., Meijer, T., Beets, C., Cleveringa, P., Laban, C. & van der Spek, A., 2005. Evidence for a middle Pleistocene glaciation of MIS 8 age in the southern North Sea. Quaternary International 133–134: 719.CrossRefGoogle Scholar
Bickel, L., Lüthgens, C., Lomax, J. & Fiebig, M., 2015. The timing of the penultimate glaciation in the northern Alpine Foreland: New insights from luminescence dating. Proceedings of the Geologists’ Association 126: 536550.CrossRefGoogle Scholar
Bridgland, D.R., Howard, A.J., White, M.J., White, T.S. & Westaway, R., 2015. New insight into the Quaternary evolution of the River Trent, UK. Proceedings of the Geologists’ Association 126: 466479.CrossRefGoogle Scholar
Busschers, F.S., Kasse, C., Van Balen, R.T., Vandenberghe, J., Cohen, K.M., Weerts, H.J.T., Wallinga, J., Johns, C., Cleveringa, P. & Bunnik, F.P.M., 2007. Late Pleistocene evolution of the Rhine in the southern North-Sea Basin: Imprints of climate change, sea-level oscillations and glacio-isostasy. Quaternary Science Reviews 26: 32163248.CrossRefGoogle Scholar
Busschers, F.S., van Balen, R.T., Cohen, K.M., Kasse, C., Weerts, H.J.T., Wallinga, J. & Bunnik, F.P.M., 2008. Response of the Rhine–Meuse fluvial system to Saalian ice-sheet dynamics. Boreas 37: 377398.CrossRefGoogle Scholar
Buylaert, J.P., Jain, M., Murray, A.S., Thomsen, K.J., Thiel, C. & Sohbati, R., 2012. A robust feldspar luminescence dating method for Middle and Late Pleistocene sediments. Boreas 41: 435451.CrossRefGoogle Scholar
Buylaert, J.P., Murray, A.S., Thomsen, K.J. & Jain, M., 2009. Testing the potential of an elevated temperature IRSL signal from K-feldspar. Radiation Measurements 44: 560565.CrossRefGoogle Scholar
Clark, C.D. & Gibbard, P.L., 2011. Chapter 7 - Pleistocene glaciation limits in Great Britain. In: Ehlers, J., Gibbard, P.L., Hughes, P.D. (eds): Quaternary glaciations - extent and chronology - A closer look. Developments in Quaternary Science, 15: 7594.CrossRefGoogle Scholar
Clark, C.E., Gibbard, P.L. & Rose, J., 2004. Glacial limits in the British Isles. In: Ehlers, J., & Gibbard, P.L. (eds): Quaternary glaciations - extent and chronology, part I: Europe. Developments in Quaternary Science, 2a. Elsevier (Amsterdam): 47–82.Google Scholar
Cohen, K.M., Gibbard, P.L. & Weerts, H.J.T., 2014. North Sea palaeogeographical reconstructions for the last 1 Ma. Netherlands Journal of Geosciences-Geologie en Mijnbouw 93: 729.CrossRefGoogle Scholar
Davies, B.J., Roberts, D.H., Bridgland, D.R., Ó Cofaigh, C., Riding, J.B., Demarchi, B., Penkman, K. & Pawley, S.M., 2012. Timing and depositional environments of a Middle Pleistocene glaciation of northeast England: New evidence from Warren House Gill, County Durham. Quaternary Science Reviews 44: 180212.CrossRefGoogle Scholar
Ehlers, J., 2011. Das Eiszeitalter. Spektrum Akademischer Verlag (Heidelberg).CrossRefGoogle Scholar
Evans, D.J.A., Roberts, D.H., Bateman, M.D., Ely, J., Medialdea, A., Burke, M.J., Chiverall, R.C., Clark, C.D., Fabel, D., 2019. A chronology for North Sea Lobe advance and recession on the Lincolnshire and Norfolk Coasts during MIS 2 and 6. Proceedings of the Geologists’ Association 130: 523540.CrossRefGoogle Scholar
Evans, D.J.A., Robert, D.H., Bateman, M.D., Clark, C.D., Medialdea, A., Callard, L., Grimoldi, E., Chiverrell, R.C., Ely, J.C., Dove, D., Ó Cofaigh, C., Saher, M., Bradwell, T., Moreton, S.G., Fabel, D., Bradley, D., 2021. Retreat dynamics of the eastern sector of the British-Irish Ice Sheet during the last glaciation. Journal of Quaternary Science 36: 723751.CrossRefGoogle Scholar
Eyles, N., Eyles, C.H. & Miall, A.D., 1983. Lithofacies types and vertical profile models; an alternative approach to the description and environmental interpretation of glacial diamict and diamictite sequences. Sedimentology 30: 393410.CrossRefGoogle Scholar
Galbraith, R.F. & Green, P.F., 1990. Estimating the component ages in a finite mixture. Nuclear Tracks and Radiation Measurements 17: 197206.CrossRefGoogle Scholar
Gale, S. & Hoare, P.G., 2012. Quaternary sediments: petrographic methods for the study of unlithified rocks. Blackburn Press.Google Scholar
Gallois, R.W., 1978. The Pleistocene history of west Norfolk. Bulletin of the Geological Society of Norfolk 30: 338.Google Scholar
Gibbard, P., 2007. Europe cut adrift. Nature 448: 259260.CrossRefGoogle ScholarPubMed
Gibbard, P.L., 1991. The Wolstonian Stage in East Anglia. In: Lewis, S.G., Whiteman, C.A. & Bridgland, D.R. (eds): Central East Anglia and the Fen Basin field guide. Quaternary Research Association (Cambridge): 713.Google Scholar
Gibbard, P.L. & Cohen, K.M., 2015. Quaternary evolution of the North Sea and the English Channel. Proceedings of the Open University Geological Society 1: 6374.Google Scholar
Gibbard, P.L., Pasanen, A.H., West, R.G., Lunkka, J.P., Boreham, S., Cohen, K.M. & Rolfe, C., 2009. Late Middle Pleistocene glaciation in East Anglia, England. Boreas 38: 504528.CrossRefGoogle Scholar
Gibbard, P.L., Peglar, S.M. & West, R.G., 2021. Late Pleistocene temperate deposits in Lincolnshire, England and their implication for the history of the River Trent system. Quaternary International 605: 2537.CrossRefGoogle Scholar
Gibbard, P.L., Turner, C. & West, R.G., 2013. The Bytham river reconsidered. Quaternary International 292: 1532.CrossRefGoogle Scholar
Gibbard, P.L., West, R.G., Andrew, R. & Pettit, M., 1991. Tottenhill. In: Lewis, S.G., Whiteman, C.A. & Bridgland, D.R. (eds): Central East Anglia and the Fen Basin field guide. Quaternary Research Association (Cambridge): 131144.Google Scholar
Gibbard, P.L., West, R.G., Andrew, R. & Pettit, M., 1992. The margin of a Middle Pleistocene ice advance at Tottenhill, Norfolk, England. Geological Magazine 129: 5976.CrossRefGoogle Scholar
Gibbard, P.L., West, R.G., Boreham, S. & Rolfe, C., 2012a. Late Middle Pleistocene ice-marginal sedimentation in East Anglia, England. Boreas 41: 319336.CrossRefGoogle Scholar
Gibbard, P.L., West, R.G., Boreham, S. & Rolfe, C., 2012b. Late Middle Pleistocene glaciofluvial sedimentation in Norfolk, England. Netherlands Journal of Geosciences 91: 6378.CrossRefGoogle Scholar
Gibbard, P.L., West, R.G. & Hughes, P.D., 2018. Pleistocene glaciation of Fenland, England, and its implications for evolution of the region. Royal Society Open Science 5: 152.CrossRefGoogle ScholarPubMed
Gibson, S.M., 2018. The Pleistocene history of the Birmingham district. PhD Thesis. University of Cambridge: 183 pp.Google Scholar
Green, C., 2011. The origins of Louth. Louth (Lindes): 177 pp.Google Scholar
Guerin, G., Mercier, N. & Adamiec, G., 2011. Dose-rate conversion factors: Update. Ancient TL 29: 58.Google Scholar
Gullentops, F. & Paulissen, E., 1978. Characteristics of the valley-floor and the valley-fill. Provisional project guide, International Geological Correlation Programme, Project 158, Subproject A: Fluvial Environments, 19–31.Google Scholar
Huntley, D.J. , & Baril, M.R., 1997. The K content of the K-feldspars being measured in optical dating or in thermoluminescence dating. Ancient TL 15: 1113.Google Scholar
Huntley, D.J & Hancock, R.J., 2001. The Rb contents of the K-feldspar grains being measured in optical dating. Ancient TL, 19: 4346.Google Scholar
Kars, R.H., Busschers, F.S. & Wallinga, J., 2012. Validating post IR-IRSL dating on K-feldspars through comparison with quartz OSL ages. Quaternary Geochronology 12: 7486.CrossRefGoogle Scholar
Laban, C. & van der Meer, J.J., 2004. Pleistocene glaciation in the Netherlands. In: Ehlers, J. & Gibbard, P.L. (eds): Quaternary glaciations - extent and chronology, part I: Europe. Developments in Quaternary Science. Elsevier: 251260.CrossRefGoogle Scholar
Lamothe, M., Auclair, M., Hamzaoui, C. & Huot, S., 2003. Towards a prediction of long-term anomalous fading of feldspar IRSL. Radiation Measurements 37: 493498.CrossRefGoogle Scholar
Lang, J., Lauer, T. & Winsemann, J., 2018. New age constraints for the Saalian glaciation in northern central Europe: Implications for the extent of ice sheets and related proglacial lake systems. Quaternary Science Reviews 180: 240259.CrossRefGoogle Scholar
Lang, J., Le Heron, D.P., Van den Berg, J.H. & Winsemann, J., 2021. Bedforms and sedimentary structures related to supercritical flows in glacigenic settings. Sedimentology 68: 15391579.CrossRefGoogle Scholar
Lewis, S.G., 1989. Shouldham Thorpe, Norfolk. In: Keen, D.H. (ed.): West Midlands. Field guide. Quaternary Research Association (London): 134135.Google Scholar
Lewis, S.G., 2012. Pleistocene stratigraphy and sedimentology. In: Boismier, W.A., Gamble, C. & Coward, F. (eds): Excavations at Lynford Quarry, Norfolk. English Heritage (Swindon): 1732.Google Scholar
Lewis, S.G. & Rose, J., 1991. Tottenhill. In: Lewis, S.G., Whiteman, C.A., Bridgland, D.R. (eds): Central East Anglia and the Fen Basin Field Guide. Quaternary Research Association (Cambridge): 145148.Google Scholar
Litt, T., Behre, K.E., Meyer, K.D., Stephan, H.J. & Wansa, S., 2007. Stratigraphische Begriffe für das Quartär des norddeutschen Vereisungsgebietes. E&G Quaternary Science Journal 56: 765.CrossRefGoogle Scholar
Litt, T., Schmincke, H.U., Frechen, M. & Schlüchter, C. 2008. Quaternary. In: McCann, T. (ed): The Geology of Central Europe. Volume 2: Mesozoic and Cenozoic. The Geological Society (London): 12871340.CrossRefGoogle Scholar
Livingstone, S.J., Piotrowski, J.A., Bateman, M.D., Ely, J.C. & Clark, C.D., 2015. Discriminating between subglacial and proglacial lake sediments: An example from the Dänischer Wohld Peninsula, northern Germany. Quaternary Science Reviews 112: 86108.CrossRefGoogle Scholar
Lukas, S., Benn, D.I., Boston, C.M., Brook, M., Coray, S., Evans, D.J., Graf, A., Kellerer-Pirklbauer, A., Kirkbride, M.P., Krabbendam, M. & Lovell, H., 2013. Clast shape analysis and clast transport paths in glacial environments: A critical review of methods and the role of lithology. Earth-Science Reviews 121: 96116.CrossRefGoogle Scholar
Mahan, S. & DeWitt, R., 2019. Principles and history of luminescence dating. In: Bateman, M.D. (ed.): The handbook of luminescence dating. Whittles Publishing: 416 pp.Google Scholar
Miall, A.D., 1978. Fluvial sedimentology. Springer Verlag (Berlin).Google Scholar
Moreau, J., 2010. The seismic analysis of the southern North Sea glaciogenic record. GRASP report No.1. Delft: The Netherlands.Google Scholar
Moreau, J., Huuse, M., Gibbard, P.L. & Moscariello, A., 2009. 3D seismic megasurvey geomorphology of the Southern North Sea, Tunnel valley record and associated ice-sheet dynamic. 71st EAGE Conference and Exhibition, 8–11 June 2009, Amsterdam, the Netherlands. Conference proceedings.CrossRefGoogle Scholar
Moreau, J., Huuse, M.,Janszen, A., van der Vegt, P., Gibbard, P.L. & Moscariello, A., 2012: The glaciogenic unconformity of the southern North Sea. Geological Society, London, Special Publications 368: 99110.CrossRefGoogle Scholar
Murray, A.S. & Wintle, A.G., 2003. Luminescence dating of quartz using an improved regenerative-dose protocol. Radiation Measurements 32: 5773.CrossRefGoogle Scholar
Paterson, T.T., 1939. Pleistocene stratigraphy of the Breckland. Nature 143: 822.CrossRefGoogle Scholar
Paterson, T.T., 1942. Lower Palaeolithic man in the Cambridge district. PhD Thesis. University of Cambridge.Google Scholar
Pawley, S.M., Bailey, R.M., Rose, J., Moorlock, B.S.P., Hamblin, R.J.O., Booth, S.J. & Lee, J.R., 2008: Age limits on Middle Pleistocene glacial sediments from OSL dating, north Norfolk, UK. Quaternary Science Reviews 2: 13631377.CrossRefGoogle Scholar
Pawley, S.M., 2006. Quaternary glaciations of north and west Norfolk. PhD Thesis. University of London: 453 pp.Google Scholar
Powers, M.C., 1953. A new roundness scale for sedimentary particles. Journal of Sedimentary Petrology 23: 117119.CrossRefGoogle Scholar
Prescott, J.R. & Hutton, J.T., 1994. Cosmic ray contributions to dose rates for luminescence and ESR dating: Large depths and long-term time variations. Radiation Measurements, 2/3: 497500.CrossRefGoogle Scholar
Rhodes, E.J., 2015. Dating sediments using potassium feldspar single-grain IRSL: Initial methodological considerations. Quaternary International 362: 1422.CrossRefGoogle Scholar
Rice, R.J., 1968. The Quaternary deposits of the central Leicestershire. Philosophical Transactions of the Royal Society of London A262: 459509.Google Scholar
Roberts, D.H., Evans, D.J.A., Callard, S.L., Clark, C.D., Bateman, M.D., Medialdea, A., Dove, D., Cotterill, C.J., Saher, M., Cofaigh, C.O., Chiverrell, R.C., Moreton, S.G., Fabel, D. & Bradwell, T., 2018. Ice marginal dynamics of the last British-Irish Ice Sheet in the southern North Sea: Ice limits, timing and the influence of the Dogger Bank. Quaternary Science Reviews 198: 181207.CrossRefGoogle Scholar
Roskosch, J., Winsemann, J., Polom, U., Brandes, C., Tsukamoto, S., Weitkamp, A., Bartholomäus, W.A., Henningsen, D. & Frechen, M., 2015. Luminescence dating of ice-marginal deposits in northern Germany: Evidence for repeated glaciations during the Middle Pleistocene (MIS 12 to MIS 6). Boreas 44: 103126.CrossRefGoogle Scholar
Rowe, P.J., Richards, D.A., Atkinson, T.C., Bottrell, S.H. & Cliff, R.A., 1997: Geochemistry and radiometric dating of a Middle Pleistocene peat. Geochimica et Cosmochimica Acta 61: 420421.CrossRefGoogle Scholar
Schenninger, J.-L., Bridgland, D.R., Howard, A.J. & White, T.S., 2007a. Optically stimulated luminescence (OSL) dating. Pleistocene sediments from the Trent Valley. English Heritage Research Department Report Series No. 57/2007.Google Scholar
Schenninger, J.-L., Bridgland, D.R., Howard, A.J. & White, T.S., 2007b. Optically stimulated luminescence dating of the Trent Valley sediments: problems and preliminary results. In: White, T.S. et al (eds): The Quaternary of the Trent Valley and adjoining regions: field guide. Quaternary Research Association (London): 6265.Google Scholar
Schwenninger, J.-L. & Rhodes, E., 2012. Optically stimulated luminescence. In: Boimeier, W.A. et al (eds): Neanderthals among mammoths, 30. English Heritage (Swindon), 67–69.Google Scholar
Scourse, J.D., Austin, W.E.N., Sejrup, H.-P. & Ansari, M.H., 1999. Foraminiferal isoleucine epimerization determinations from the Nar Valley Clay, Norfolk, UK: Implications for Quaternary correlations in the southern North Sea basin. Geological Magazine 136: 543560.CrossRefGoogle Scholar
Shotton, F.W., 1953. The Pleistocene deposits of the area between Coventry, Rugby and Leamington, and their bearing on the topographic development of the Midlands. Philosophical Transactions of the Royal Society of London B237: 209260.Google Scholar
Sneed, E.D. & Folk, R.L., 1958. Pebbles in the lower Colorado River, Texas: a study in particle morphogenesis. Journal of Geology 66: 114150.CrossRefGoogle Scholar
Spooner, N. 1994. The anomalous fading of infrared-stimulated luminescence from feldspars. Radiation Measurements 23: 625632.CrossRefGoogle Scholar
Straw, A., 2000. Some observations on ‘Eastern England’ in ‘A Revised Correlation of Quaternary deposits in the British Isles’. In: Bowen, D.Q. (ed.): Quaternary Newsletter, 91: 2–6.Google Scholar
Straw, A., 2005. Glacial and pre-glacial deposits at Welton-le-Wold, Lincolnshire. Straw, Exeter: 39 pp.Google Scholar
Straw, A., 2011. The Saale glaciation of Eastern England. Quaternary Newsletter 123: 2835.Google Scholar
Toucanne, S., Zaragosi, S., Bourillet, J.F., Cremer, M., Eynaud, F., Van Vliet-Lanoe, B., Penaud, A., Fontanier, C., Turon, J.L., Cortijo, E. & Gibbard, P.L., 2009. Timing of massive ‘Fleuve Manche’ discharges over the last 350 kyr: Insights into the European ice-sheet oscillations and the European drainage network from MIS 10 to 2. Quaternary Science Reviews 28: 12381256.CrossRefGoogle Scholar
Turner, C., Gibbard, P.L. & West, R.G., 2020. The Leet Hill site: a correction. A response to ‘Spotlight on a site” – Leet Hill, Norfolk, England. Quaternary Newsletter 151: 714.Google Scholar
Ventris, P.A., 1985. Pleistocene environmental history of the Nar Valley, Norfolk. PhD Thesis. University of Cambridge.Google Scholar
Ventris, P.A., 1986. The Nar Valley. In: West, R.G. & Whiteman, C.A. (eds): The Nar Valley and North Norfolk, Field Guide, Quaternary Research Association (Coventry): 6–55.Google Scholar
Ventris, P.A., 1996. Hoxnian Interglacial freshwater and marine deposits in northwest Norfolk, England and their implications for sea-level reconstruction. Quaternary Science Reviews 15: 437450.CrossRefGoogle Scholar
Voinchet, P., Moreno, D., Bahain, J.J., Tissoux, H., Tombret, O., Falguères, C., Moncel, M.H., Schreve, D., Candy, I., Antoine, P. & Ashton, N., 2015. New chronological data (ESR and ESR/U-series) for the earliest Acheulian sites of north-western Europe. Journal of Quaternary Science 30: 610622.CrossRefGoogle Scholar
Walker, M., 2005. Quaternary dating methods. John Wiley and Sons (Chichester).Google Scholar
West, R.G. & Gibbard, P.L., 2021. On the Palaeolithic site at Three Hills, Warren Hill, Mildenhall, Suffolk, England. Bulletin of the Geological Society of Norfolk 71: 1341.Google Scholar
West, R.G., Gibbard, P.L., Boreham, S. & Rolfe, C., 2014. Geology and geomorphology of the Palaeolithic site at High Lodge, Mildenhall, Suffolk, England. Proceedings of the Yorkshire Geological Society 60: 99121.CrossRefGoogle Scholar
West, R.G., 2017. Patterned ground and superficial deposits at Hare Park, Swaffham Bulbeck, Cambridgeshire, England. Proceedings of the Yorkshire Geological Society 62: 197216.CrossRefGoogle Scholar
White, T.S., Bridgland, D.R., Westaway, R., Howard, A.J. & White, M.J., 2010. Evidence from the Trent terrace archive, Lincolnshire, UK, for lowland glaciation of Britain during the Middle and Late Pleistocene. Proceedings of the Geologists’ Association 121: 141153.CrossRefGoogle Scholar
White, T.S., Bridgland, D.R., Westaway, R. & Straw, A., 2017. Evidence for late Middle Pleistocene glaciation of the British margin of the southern North Sea. Journal of Quaternary Science 32: 261275.CrossRefGoogle Scholar
Zagwijn, W.H., 1973. Pollenanalytic studies of Holsteinian and Saalian beds in the northern Netherlands. Mededelingen Rijks Geologische Dienst 24: 139156.Google Scholar
Figure 0

Fig. 1. a. Location map showing western East Anglia and the Fenland basin study area. 1b. The proposed glaciation limits for eastern England based on Clark and Gibbard (2011) and Gibbard et al. (2018) (solid lines), the limit for the possible Middle Wolstonian ‘MIS 8’ glaciation postulated by White et al. (2017) (dotted line). For site localities see Fig. 1a.

Figure 1

Fig. 2. Quaternary geological map of the study region, showing the glacial deposits, gravel spreads and the Fenland Holocene deposits. The approximate ‘Skertchly Line’ glacial maximum limit is also shown. Map source: EDINA.

Figure 2

Fig. 3. Schematic palaeogeography showing the maximum extent of the Tottenhill glacial lobe in Fenland (Late Wolstonian Substage) and associated drainage alignments and glacial lakes (modified from Gibbard et al. 2018). The blue arrows indicate the direction of ice advance. For site localities see Fig. 1a.

Figure 3

Table 1. Geological timetable of events in the Fenland region, eastern England, and their correlation to the near Continent during the Middle to Late Pleistocene subseries (modified from Gibbard et al., 2018). The NW European chronostratigraphy/climatostratigraphy is modified from Litt et al. (2007, 2008) and Roskosch et al. (2015). For further explanation see the text.

Figure 4

Figure 4. Luminescence sample localities for the Maidscross Hill site with the approximate positions of IRSL samples and pIRIR225 ages shown on the stratigraphic log of Gibbard et al (2009).

Figure 5

Figure 5. Luminescence sample localities for the Shouldham Thorpe site with the approximate positions of IRSL samples and pIRIR225 ages shown on the composite stratigraphic log of Gibbard et al (2012b).

Figure 6

Figure 6. Composite log with Luminescence sample localities and pIRIR225 ages for the Watlington Site. Note vertically aligned clasts adjacent to sand filled cryoturbation feature.

Figure 7

Figure 7. Cryoturbation structures found at Watlington Quarry. (A) vertical profile through structures which repeat and Irregular Intervals with (B) annotated version showing feature boundaries. (C) planform of cryoturbation structure with (D) vertical profile through same structure. (E) cleared quarry floor showing frequency of structures within a ∼50 m2 area (photograph courtesy of Vince Spall) with (F) annotated version showing feature boundaries.

Figure 8

Figure 8. Example IRSL data from sample Shfd18077. (A) and (B) Shine down curves showing rapid trap emptying with IRSL50 and IRSL225 stimulation. (C) and (D) SAR growth curves of the same aliquot measured with IRSL50 (C) and IRSL225 (D). Note where red line intersects the X axis showing a higher recovered Dose for the IRSL225 measurement. (E) SAR growth curve measured with IRSL50 showing a saturated aliquot where the natural dose plotted on the Y axis does not intersect the SAR growth curve. (F) SAR growth curve measured with IRSL50 showing an aliquot best fitted by a single saturating exponential + linear curve to obtain a De value.

Figure 9

Table 2. Luminescence related data for sampled sites.

Figure 10

Figure 9. Sediment characterisation of the Watlington Gravels (A) Shape (B) Roundness/Angularity (C) Particle size distribution of Watlington Gravels.

Figure 11

Figure 10. Roundness indices applied to the Watlington Gravels indicating (as per Lukas et al2013) a sub-glacial origin. (A) the C40/RA covariance where the RA index for roundness is calculated as the percentage of angular and very angular clast in a sample (B) the C40/RWR covariance where RWR index is calculated as the percentage of rounded and well-rounded clast in the same sample.

Figure 12

Figure 11. Postulated maximum limit of the Wolstonian Tottenhill and equivalent Drenthe glacial lobes in the southern North Sea basin. Modified from Gibson (2018) and Gibbard et al 2009).