Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-26T06:57:33.211Z Has data issue: false hasContentIssue false

A great wave: the Storegga tsunami and the end of Doggerland?

Published online by Cambridge University Press:  01 December 2020

James Walker
Affiliation:
School of Archaeological and Forensic Science, University of Bradford, UK
Vincent Gaffney*
Affiliation:
School of Archaeological and Forensic Science, University of Bradford, UK
Simon Fitch
Affiliation:
School of Archaeological and Forensic Science, University of Bradford, UK
Merle Muru
Affiliation:
School of Archaeological and Forensic Science, University of Bradford, UK Department of Geography, Institute of Ecology and Earth Sciences, University of Tartu, Estonia
Andrew Fraser
Affiliation:
School of Archaeological and Forensic Science, University of Bradford, UK
Martin Bates
Affiliation:
School of Archaeology, History and Anthropology, University of Wales Trinity Saint David, UK
Richard Bates
Affiliation:
School of Earth & Environmental Sciences, University of St Andrews, Scotland, UK
*
*Author for correspondence: ✉ [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Around 8150 BP, the Storegga tsunami struck North-west Europe. The size of this wave has led many to assume that it had a devastating impact upon contemporaneous Mesolithic communities, including the final inundation of Doggerland, the now submerged Mesolithic North Sea landscape. Here, the authors present the first evidence of the tsunami from the southern North Sea, and suggest that traditional notions of a catastrophically destructive event may need rethinking. In providing a more nuanced interpretation by incorporating the role of local topographic variation within the study of the Storegga event, we are better placed to understand the impact of such dramatic occurrences and their larger significance in settlement studies.

Type
Research 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 (http://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
Copyright © The Author(s), 2020. Published by Cambridge University Press on behalf of Antiquity Publications Ltd

Introduction

In an age of human-induced climate change, catastrophic natural disasters appear to be occurring with greater frequency and magnitude. Tsunamis, such as the 2004 Indian Ocean ‘Boxing Day’ and 2011 Tōhoku (Japan) events, are of particular note, striking quickly and with little warning (Seneviratne et al. Reference Seneviratne and Field2012). Although such events have fuelled interest in how people in the past responded to natural disasters (e.g. Burroughs Reference Burroughs2005; Cain et al. Reference Cain, Goff and McFadgen2018), archaeology has—with few exceptions (e.g. McFadgen Reference McFadgen2007)—been slow to engage in the debate beyond historically attested examples, leaving the sciences to take the lead in palaeotsunami research (Goff et al. Reference Goff, Chagué-Goff, Nichol, Jaffe and Dominey-Howes2012; Engel et al. Reference Engel, Pilarczyk, May, Brill and Garrett2020).

The Storegga tsunami (c. 8150 cal BP) provides a comparative phenomenon within North-west European prehistory. It is geologically well attested (Figure 1), with evidence from Western Scandinavia, the Faroe Isles, north-east Britain, Denmark and Greenland. Caused by the largest known Holocene submarine landslides (80 000km2), the event displaced 3200km3 of sediment (Haflidason et al. Reference Haflidason, Lien, Sjerup, Forsberg and Bryn2005) on the European continental shelf west of southern Norway. The resulting tsunami must have been of considerable proportions (Bugge Reference Bugge1983; Bugge et al. Reference Bugge, Befring, Belderson, Eidvin, Jansen, Kenyon, Holtedahl and Sejrup1987; Dawson et al. Reference Dawson, Long and Smith1988; Long et al. Reference Long, Smith and Dawson1989a), and has even been posited as causing the final inundation of Mesolithic Doggerland, the now submerged palaeolandscape of the southern-central North Sea (Weninger et al. Reference Weninger2008). Specifically archaeological evidence for the tsunami, however, is scarce.

Figure 1. a) Map showing the Storegga Slide and sites where tsunami deposits have been found; b) ‘Europe's Lost Frontiers’ project coring locations, with ELF001A highlighted (topography: National Oceanic and Atmospheric Administration 2009; bathymetry: EMODnet 2018; image by M. Muru).

To date, only two Mesolithic sites have been confirmed as underlying Storegga deposits (Figure 1; Bondevik Reference Bondevik and Meyers2019: 29), although others remain a possibility (e.g. Bondevik Reference Bondevik2003). Hijma (Reference Hijma2009: 140–41) notes that “an important question is whether the Storegga tsunami had sufficient force to create a distinct deposit where it dissipated on the southern North Sea shores” or whether “most of the energy had already dissipated […] across the shallowest parts of the contemporary North Sea” (see also Cohen & Hijma Reference Cohen and Hijma2008). The dearth of archaeological evidence suggests the need to examine why archaeologists struggle to define natural disasters in the past. In doing so, this article reviews models of the Storegga tsunami's impact. Using new data (Gaffney et al. Reference Gaffney2020), we re-evaluate the fate of Doggerland and consider the first offshore evidence for the tsunami from the southern-central North Sea.

The archaeology of natural disasters

The archaeology of natural disasters is an emerging field (Faas & Barrios Reference Faas and Barrios2015) that provides the capacity to assess such events in terms of longer-term impacts on lifeways, whereas studies of contemporary natural disasters tend to concentrate on the immediate loss of life (Torrence & Grattan Reference Torrence, Grattan, Torrence and Grattan2002). The devastation wrought by the Indian Ocean and Tōhoku tsunamis, for example, led to both being labelled as ‘mega-tsunamis’ in the media, although neither meet the technical criteria for this description (Goff et al. Reference Goff, Terry, Chagué-Goff and Goto2014: 13). Clearly, scales of time, space and consequence are important for how we understand catastrophic phenomena (see Estévez Reference Estévez, Buchet, Rigeade, Séguy and Signoli2008). It may seem obvious that for a natural disaster to qualify as truly catastrophic, a society must have struggled or failed to adapt to changes in their environment (Oliver-Smith Reference Oliver-Smith1996: 303). Intuitively, however, we recognise that ‘catastrophes’ and ‘natural disasters’ may be understood and experienced with a high degree of subjectivity.

Prehistoric catastrophes and the marine environment

Underwater survey and excavation techniques are among the fastest developing areas of methodological advancement in archaeology (see Fitch et al. Reference Fitch, Thomson and Gaffney2005; Bailey et al. Reference Bailey, Harff and Sakellariou2017; Sturt et al. Reference Sturt, Flemming, Carabias, Jöns and Adams2018). Despite this, data collection beyond the near-shore remains challenging. The difficulties of identifying specific events in such environments—even at the scale of the Storegga slide—remain significant. Consequently, the Storegga tsunami exemplifies the paradoxical scenario described by Torrence and Grattan (Reference Torrence, Grattan, Torrence and Grattan2002: 4) whereby archaeological evidence for the impact of an unusually destructive force upon extant cultures remains elusive. There is an unwitting tendency to adopt a progressivist lens and to presume that hunter-gatherers and early farmers of the past and present were and are less capable of dealing with extreme environmental forces (Bettinger et al. Reference Bettinger, Garvey and Tushingham2015: 12). This is compounded by challenges in identifying catastrophic events archaeologically on conventional, terrestrial sites—particularly in prehistory, where hiatuses in deposition may result from many processes. The transient nature of even ‘permanent’ hunter-gatherer settlements raises questions about how we might recognise responses to environmental change (Moe Astrup Reference Moe Astrup2018: 136).

In many cases, the effects of catastrophic natural disasters may be easier to recognise than evidence for the disaster itself. Goff et al. (Reference Goff, Chagué-Goff, Nichol, Jaffe and Dominey-Howes2012) offer guidelines for identifying archaeological proxies of palaeotsunamis. These include changes in shell-midden composition, structural damage, geomorphological changes (e.g. uplift, subsidence and/or compaction) and replication of these features across multiple sites. In European Mesolithic contexts, however, these proxies can be elusive, as, for example, structural evidence is rare, and variation in shell-midden composition may be attributed to multiple causes.

Searching for Storegga

After initial reports of the geological indicators of the Storegga tsunami emerged in the 1980s, evidence from archaeological deposits soon followed (Dawson et al. Reference Dawson, Smith and Long1990). Since then, however, the number of associated archaeological sites has remained small (Figure 1; Bondevik Reference Bondevik2003). This may reflect a lack of access to appropriate geological expertise (cf. Long et al. Reference Long, Dawson and Smith1989b: 535), difficulties in distinguishing tsunami deposits from storm surges and other transgressive episodes (Bondevik et al. Reference Bondevik, Svendsen and Mangerud1998), or a lack of contemporaneous archaeological sites. Alternatively, the evidence may simply not exist: a tsunami needs a run-up of only 1m to be catastrophic, yet less than 5m is often too little to leave a geological record (Lowe & de Lange Reference Lowe and de Lange2000: 403). Furthermore, tsunamis may erode the landscape, removing any archaeological evidence, while remaining cultural debris may have been cleared by returning people, or simply missed through limited excavation strategies. Hence, a tsunami may cause terrible damage, but leave little archaeological evidence. Finally, the Storegga tsunami coincided with the harshest conditions of the 8.2 ka ‘cold snap’ (Dawson et al. Reference Dawson, Bondevik and Teller2011; Bondevik et al. Reference Bondevik, Stormo and Skjerdal2012; Rydgren & Bondevik Reference Rydgren and Bondevik2015). Separating tsunami impacts from those resulting from this broader climatic downturn is challenging.

The proxies outlined by Goff et al. (Reference Goff, Chagué-Goff, Nichol, Jaffe and Dominey-Howes2012) have so far been lacking from the North Sea basin, with archaeological evidence comprising either unconfirmed tsunami deposits or speculative stratigraphic relationships. Even where Storegga deposits are confirmed as overlying Mesolithic occupations—including Castle Street in Scotland, and Dysvikja, and probably Fjørtoft, in Norway (Dawson et al. Reference Dawson, Smith and Long1990; Bondevik Reference Bondevik2003, Reference Bondevik and Meyers2019)—these cannot be taken as reliable evidence of immediate event impact (Bondevik Reference Bondevik and Meyers2019: 29; Table S1 in the online supplementary material (OSM)).

Reconstructions of what happened to Doggerland rely on terrestrial, primarily geological, data, and have been impeded by a lack of clarity as to what constitutes a contemporaneous landmass. Some have envisioned that Doggerland had all but disappeared prior to Storegga (e.g. Edwards Reference Edwards and Saville2004: 67), while others have proposed that the tsunami constituted the final inundation process (Weninger et al. Reference Weninger2008: 13). Others still have suggested that at the time of the tsunami, Doggerland had already become a (populated) island (Hill et al. Reference Hill, Avdis, Mouradian, Collins and Piggott2017: 1). Assessing these different interpretations requires a nuanced history of the southern North Sea landscape.

A three-stage history of gradual inundation

The integration of palaeobathymetry and seismic analyses (e.g. Gaffney et al. Reference Gaffney, Thomson and Fitch2007), and progress in refining estimates of sea-level rise (Hijma et al. Reference Hijma and Cohen2010, Reference Hijma and Cohen2019; Shennan et al. Reference Shennan, Bradley and Edwards2018; Emery et al. Reference Emery, Hodgson, Barlow, Carrivick, Cotterill, Mellett and Booth2019), have allowed us to characterise the nature and extent of the prehistoric landmass in the southern North Sea (Figure 2). ‘Doggerland’ typically refers to the entire submerged landscape stretching from the Dover/Calais Strait to the Norwegian Sea (Coles Reference Coles1998). This landmass, however, would have changed significantly in extent and character since the Last Glacial Maximum, and the ‘catch-all’ name of Doggerland may not be particularly useful.

Figure 2. North Sea coastline reconstructions for: a) Doggerland c. 10 000 cal BP; b) Dogger Archipelago c. 9000 cal BP; c) Dogger Archipelago c. 8200 cal BP; d) Dogger Littoral c. 7000 cal BP (image by M. Muru).

Doggerland and the Dogger Hills

The extent of Doggerland during the Late Pleistocene is debated. Early Holocene Doggerland probably constituted a landscape stretching from Yorkshire to Denmark, with the Dogger Hills as a modest upland zone at its northernmost limit (Figure 2a). Subsequently, however, Doggerland became increasingly diminished and fragmented (Cohen et al. Reference Cohen, Westley, Erkens, Hijma, Weerts, Flemming, Harff, Moura, Burgess and Bailey2017: 162).

The Dogger Archipelago and Dogger Island

By 9000 cal BP, Doggerland would have been fragmented to the degree that it no longer resembled the continuous landscape often portrayed in the literature (e.g. Coles Reference Coles1998). The uplands, comprising the current Dogger Bank, would probably have been cut off (Figure 2b), forming Dogger Island, which survived for approximately another millennium. The rapidity of sea-level rise around this time (Hijma & Cohen Reference Hijma and Cohen2010) complicates assessment of the period for which this island remained an attractive ecological zone for exploitation or viable settlement. The broader landscape became increasingly fragmented by the formation of estuaries, inlets and islands (Gearey et al. Reference Gearey, Hopla, Boomer, Smith, Marshall, Fitch, Griffiths, Tappin, Williams, Hill, Boomer and Wilkinson2017: 49). From this period onwards—and certainly following the significant sea-level rise associated with the 8.2 ka event—it would be better to conceive of this landscape as the ‘Dogger Archipelago’.

The Dogger Littoral

Between 8400 and 8200 cal BP, the global average sea level rose (possibly in two phases) between 1 and 4m (Hijma & Cohen Reference Hijma and Cohen2019: 83). By the time the tsunami struck, c. 8150 BP, this higher sea level had probably reduced Dogger Island to a shallow sand bank (Hijma & Cohen Reference Hijma and Cohen2010, Reference Hijma and Cohen2019; Törnqvist & Hijma Reference Törnqvist and Hijma2012; Emery et al. Reference Emery, Hodgson, Barlow, Carrivick, Cotterill, Mellett and Booth2019). Reconstructing the contemporaneous shoreline using bathymetry and the relative sea-level curve (Shennan et al. Reference Shennan, Bradley and Edwards2018) indicates the possible survival of a small area (approximately 1000km2), comprising the highest terrain, south of the present-day sand bank (Figure 2c)—even assuming the maximal estimate of a 4m sea-level rise (Emery et al. Reference Emery, Hodgson, Barlow, Carrivick, Cotterill, Mellett and Booth2019). Many of the smaller islands to the south may also have remained above water (Peeters et al. Reference Peeters, Murphy and Flemming2009: 21; Garrow & Sturt Reference Garrow and Sturt2011: 63).

Around 7000 cal BP, approximately 1150 years after the tsunami, Dogger Island would presumably have disappeared and the number of islands reduced to a handful (Figure 2d). The shoreline of Denmark, north-west Germany, the Netherlands, Belgium and southern Britain continued to exist someway beyond their present extents, in some cases, such as the Wash in East Anglia, by several tens of kilometres. This is evidenced by the use of such coastal margins well into the Neolithic and later—as demonstrated by sites such as Seahenge off the UK coast and the many Late Mesolithic sites of the Danish nearshore. By this point, the remnants of Doggerland would cumulatively have still constituted a sizeable area: the ‘Dogger Littoral’ (Figure 2d).

Archaeological impact models

With a detailed understanding of the evolution of the landscape in place, competing models of the tsunami's impact may now be assessed. Two models relate to the impact on (extant) terrestrial landscapes (Waddington & Wicks Reference Waddington and Wicks2017; Blankholm Reference Blankholm2020), while two others concern the inundated southern North Sea landscape (Weninger et al. Reference Weninger2008; Hill et al. Reference Hill, Collins, Avdis, Kramer and Piggott2014, Reference Hill, Avdis, Mouradian, Collins and Piggott2017).

‘Doggerland’ wipeout scenario

To estimate the impact of Storegga, Weninger and colleagues (Reference Weninger2008) used dated sediments from Norway, Britain and Greenland that relate stratigraphically to tsunami deposits, along with bathymetric 3D modelling of the southern North Sea. They concluded that the Dogger Bank was probably submerged at the time of the tsunami, meaning that the wave may have reached the northern shores of present-day lowland Europe (Weninger et al. Reference Weninger2008). Without the barrier of the Dogger Bank, they argue that the Dogger Archipelago would have experienced devastating inundation with “a catastrophic impact on the contemporary coastal Mesolithic population” (Weninger et al. Reference Weninger2008: 17).

Dogger Bank survival scenario

An alternative scenario is advanced by Hill et al. (Reference Hill, Avdis, Mouradian, Collins and Piggott2017) using multiscale numeric modelling. Assuming the Dogger Bank to still have been both exposed and inhabited by Mesolithic communities, they initially proposed that the tsunami may have been catastrophic (Hill et al. Reference Hill, Collins, Avdis, Kramer and Piggott2014), but subsequently revised this position, concluding that a maximal inundation would have covered around 35 per cent of the exposed landmass—potentially similar to an extreme high tide (Hill et al. Reference Hill, Avdis, Mouradian, Collins and Piggott2017: 10). The authors, however, do not consider the presence of other landforms, and the pre-Storegga submergence of much of Dogger Island (Emery et al. Reference Emery, Hodgson, Barlow, Carrivick, Cotterill, Mellett and Booth2019) challenges this position.

Terrestrial models

The loss of coastline south of the isostatic readjustment margin since Storegga means that much currently extant landmass may be peripheral to the areas worst affected. Unlike sites along the Scottish and Norwegian coast, areas affected by the tsunami in the southern North Sea basin are likely to be under water, making it difficult to evaluate impact. Two recent studies, however, present archaeological evidence from north-east Britain and northern Norway for the terrestrial impact of the tsunami (Waddington & Wicks Reference Waddington and Wicks2017; Blankholm Reference Blankholm2020).

Waddington and Wicks (Reference Waddington and Wicks2017: fig. 4) observe a drop in the number of sites on the north-east coast of Britain prior to the tsunami, with a slow population rebound centred at c. 8000 cal BP. They argue that this is due to the tsunami scouring recently deposited archaeological remains from the Mesolithic coast. Although this interpretation is difficult to verify, subduction-based tsunami modelling suggests that scouring is strongest during the drawdown stage of a tsunami (Yeh & Li Reference Yeh, Li and Sekiguchi2008: 100), prior to the wave breaking on land. Furthermore, there appear to be no discernible changes in settlement type or artefacts associated with the time of the tsunami, although Waddington and Wicks (Reference Waddington and Wicks2017: 708) argue that this supports an externally induced drop in site density.

Typically, tsunami deposits rest unconformably on underlying strata, and are interpreted as being indicative of erosive events (Dawson Reference Dawson, Smith and Long1994: 88). It is, however, difficult to ascertain the severity of the erosion and whether it was sufficient to destroy or obscure centuries of human activity. Following the December 1992 tsunami that hit Flores in Indonesia, a conspicuous relationship between run-up height and erosion was observed. The maximal inundation distance for this tsunami, recorded along one river valley, was approximately 600m, but where run-up heights ranged between 1 and 4m along the northern coastal line of Flores, erosion was restricted to a narrow coastal strip (Shi & Smith Reference Shi and Smith2003: 191). Storegga run-up heights recorded from the UK mainland rarely exceed 4m, and would probably only surpass 5m in inlets and channels where wave energy could be focused (Smith et al. Reference Smith2004), especially south of the Forth estuary (Long Reference Long, Scourse, Chapman, Tappin and Wallis2018: 150).

While the Flores tsunami provides a rare example where it has been possible to investigate this relationship, it is not necessarily a suitable analogue. For Storegga, run-up heights—as inferred from field observations—are widely considered to represent minimal estimates (Dawson Reference Dawson, Smith and Long1994: 88), and may actually have been metres higher (Dawson Reference Dawson, Smith and Long1994; Smith et al. Reference Smith2004; Long Reference Long, Scourse, Chapman, Tappin and Wallis2018). Onshore tsunami geomorphology remains relatively poorly understood (although see Engel et al. Reference Engel, Pilarczyk, May, Brill and Garrett2020 for recent advancements), and wave run-up and backwash both have significant potential for surficial erosion (Sugawara et al. Reference Sugawara, Minoura, Imamura, Shiki, Tsuji, Yamazaki and Minoura2008). Ultimately, however, onshore wave velocities and, therefore, processes of sediment transportation and reworking will have been contingent upon local coastal topography (Dawson & Shi Reference Dawson and Shi2000; Gaffney et al. Reference Gaffney2020).

The Norwegian Varangerfjord study comprises a smaller area that is unrelated to the southern North Sea basin, and further removed from the location of the slides than north-east Britain. Varangerfjord is a relatively well protected, east-facing inlet with peninsulas to the west (Corner et al. Reference Corner, Yevzerov, Kolka and Møller1999: 147). Like Waddington and Wicks (Reference Waddington and Wicks2017), Blankholm (Reference Blankholm2020) notes a drop in the number of sites, but, in the absence of well-dated deposits, he is restricted to correlating this with elevation (26–28m asl), approximately 2–3m above the 8100 BP shoreline. Furthermore, there is no clear geological signature for the tsunami in this region, perhaps because it simply did not obtain a significant run-up height. Consequently, it is questionable to what extent the tsunami had an impact here (Blankholm Reference Blankholm2020).

Review of models

Neither the Varangerfjord nor UK models present compelling evidence of forced cultural change (cf. Torrence & Grattan Reference Torrence, Grattan, Torrence and Grattan2002) through conventional forms of material culture. Blankholm (Reference Blankholm2020) advocates caution, given the limited available data and potential for alternative ethnoarchaeological and taphonomic explanations for the site distribution patterns observed. Waddington and Wicks (Reference Waddington and Wicks2017), however, believe that the paucity of sites contemporaneous with—and centuries before—the tsunami results from the erosive force of its run-up.

The work of Weninger et al. (Reference Weninger2008) represents a tour de force of archaeological inference, exploring effects of a severe inundation in a way not previously attempted. Their assessment, however, does not consider the shoaling effect of the Dogger Bank. After reducing speed and increasing in amplification while passing over the shallow bank, wave energy would have dissipated upon re-entering deeper waters to the south. Furthermore, the rising waters were probably anything but “inexorable” (Weninger et al. Reference Weninger2008: 16). Tsunamis, like normal waves, break and then subside. Consequently, even following catastrophic inundation, the effect would not necessarily have led to permanent inundation. Although the tsunami may have devastated the remnant Dogger Island, it remains uncertain whether it was inhabited at this time. If it was, the hilly local topography may have offered some shelter from the impact.

Finally, although Hill et al.'s (Reference Hill, Collins, Avdis, Kramer and Piggott2014) model is not fully applicable—as Dogger Island was probably considerably smaller than posited when the tsunami struck (Figure 2c)—it nevertheless provides insight into how Storegga may have affected other low-lying landmasses. Even in a low-drag scenario with conservative wave-energy dissipation, it still predicts the survival of Dogger Island (Hill et al. Reference Hill, Avdis, Mouradian, Collins and Piggott2017)—without taking into account the effects of any extant vegetation cover (for a discussion of the arboreal effects on dissipation and inundation, see Cochard Reference Cochard2011).

Modern-day risk assessment models

Concerns about a future repeat of Storegga have prompted modern risk assessments (Chacón-Barrantes et al. Reference Chacón-Barrantes, Rangaswami and Mayerle2013). One model that focuses on the Dutch coast relocates the origin point of the tsunami to the entrance of the Norwegian trench, in order to provide a ‘maximal credible event’ scenario (Kulkarni et al. Reference Kulkarni, Zimmerman, Lanckriet, Breugem, Dorfmann and Zenz2017). Despite its fast rate of travel, the simulated tsunami failed to either breach or overtop the protective dune system on the Dutch foreshore, other than at its natural openings. Even here, waves failed to penetrate a second dune-line, and reached no more than 1km inland (Kulkarni et al. Reference Kulkarni, Zimmerman, Lanckriet, Breugem, Dorfmann and Zenz2017). The peak run-up was 7.5m, and the maximum inundation depth was 3.5m in a single, highly localised dune breach (Kulkarni et al. Reference Kulkarni, Zimmerman, Lanckriet, Breugem, Dorfmann and Zenz2017: 28). Furthermore, the run-up for the North Sea basin to the south of the Dogger Bank may have been less: the Storegga run-up heights (up to 5m) observed from south of the Forth estuary typically decrease in height farther south along the British coastline (Long Reference Long, Scourse, Chapman, Tappin and Wallis2018: fig. 6).

Variable run-up heights and sedimentation thicknesses attest to the importance of local topography in influencing the effects of coastal, wave-derived phenomena. Dawson et al. (Reference Dawson, Dawson, Bondevik, Costa, Hill and Stewart2020) attribute discrepancies between field observations and numerical simulations of run-up heights from the Shetland Islands to the influence of incising inlets and valleys. Even microtopography can have a significant influence. A winter storm surge in the southern North Sea in 2013, for example, produced run-up heights that varied by as much as 2m in the same locale at Holkham in Norfolk (Spencer et al. Reference Spencer, Brooks, Möller and Evans2014). This, combined with the highly localised inundation effects modelled by Kulkarni et al. (Reference Kulkarni, Zimmerman, Lanckriet, Breugem, Dorfmann and Zenz2017), and the caution that Mesolithic hunter-gatherers may have exercised to avoid danger zones (Leary Reference Leary2015: 80; Blankholm Reference Blankholm2020), suggests that we may need to revise our perception of Storegga as being universally devastating: a catastrophe for one group may be a ‘near miss’ for another.

New data from Doggerland

The influence of topography on the destructive potential of tsunamis has recently been affirmed by the recovery of the first evidence for the Storegga tsunami from the southern North Sea (Gaffney et al. Reference Gaffney2020). In 2018, a series of vibrocore samples were taken from palaeo-river channel systems associated with the Outer Dowsing Deep, as part of the ERC-funded project ‘Europe's Lost Frontiers’ (Gaffney et al. Reference Gaffney2020). Several cores contained ‘tsunami-like’ deposits, comprising clastic sediments, stones and broken shells, evincing a much higher level of turbation and accelerated deposition than the laminar sediments that bracket them. Multiproxy analyses of core ELF001A (Figure 3), including sedimentology, palaeomagnetic, isotopic, palaeobotany and sedaDNA techniques, confirm this assessment. Optically stimulated luminescence (OSL) dating sequences indicate that these deposits were broadly contemporaneous with Storegga (see Gaffney et al. Reference Gaffney2020; Figure S1 & Table S2).

Figure 3. Stratigraphic units in core ELF001A (for full details, see Figure S1 & Table S2 in the online supplementary material; image by M. Muru & M. Bates).

The location of these deposits—42km inland from the present coastline (Figure 1b)—is striking, and their absence from other nearby cores reflects the importance of valleys and inlets in channelling wave-energy (Smith et al. Reference Smith2004; Gaffney et al. Reference Gaffney2020). Seismological mapping shows that, during the Early Holocene, the Dogger Bank (Cotterill et al. Reference Cotterill, James, Forsberg, Tjelta, Carter and Dove2017), along with other areas of Doggerland (Gaffney et al. Reference Gaffney, Thomson and Fitch2007), would have featured numerous fluvial-cut and glacial-infilled features that would have allowed for a highly variable inflow of water. The tsunami wave run-up in the area around core ELF001A can be estimated using bathymetry and the altitude of tsunami deposits within the core (Figures 3–4; Gaffney et al. Reference Gaffney2020). The remnant of Dogger Island may have acted as a physical barrier to the wave for areas to the south. The remaining submerged areas would have been particularly shallow at the time of the tsunami, and may have sheltered some areas to the south by causing the wave to prematurely shoal and dissipate, as seen in the Dogger Bank's influence on diurnal tides today (e.g. Pingree & Griffiths Reference Pingree and Griffiths1982). This shallow bank or low-lying island may, however, also have exacerbated the impact of the tsunami in other areas, focusing wave energy to the east and west of the bank, including the head of the Outer Dowsing Deep and the basin from which core ELF001A was retrieved (Figure 4).

Figure 4. Model showing the Storegga tsunami and run-up around the western sector of the southern North Sea at 8150 cal BP (image by M. Muru).

Notably, sedaDNA evidence from the cores (Gaffney et al. Reference Gaffney2020) suggests a withdrawal of floodwaters and recovery of the land on the Dogger Littoral. Hence, the eventual inundation of the remaining parts of Doggerland resulted from the inexorable sea-level rise, rather than a lasting inundation from the Storegga tsunami.

Discussion

The Storegga tsunami was undoubtedly devastating for some regions. What was left of Dogger Island may have been particularly badly affected. The inlets and coastal valleys on the plains west of the Dogger Bank, however, may have been among the worst affected areas. In other locations, including areas protected by the Dogger Bank/Island, the impact may have been relatively limited. Nevertheless, the effects on any Mesolithic communities inhabiting the southern North Sea landscape remain, at present, difficult to gauge. As localised topographical variability is brought into focus, however, it seems increasingly untenable to maintain scenarios of wholesale catastrophic destruction or the definitive inundation of the last vestiges of Doggerland.

The prospect of the Dogger Littoral surviving the tsunami carries important implications for the prehistory of North-west Europe. The potential continuity of remnants of Doggerland into the Neolithic—as first proposed by Coles (Reference Coles, Coles, Coles and Jørgensen1999)—has been neglected due to the popularity of the notion of a catastrophic final inundation. It is typically assumed that ‘Doggerland’ had all but disappeared by the onset of the Neolithic (Cohen et al. Reference Cohen, Westley, Erkens, Hijma, Weerts, Flemming, Harff, Moura, Burgess and Bailey2017: 169). In the final stages of the European Mesolithic, hunter-gatherers formed a cultural, if not territorial, buffer between the incoming Linear Pottery Culture and the coasts. Increasingly, it seems that the spread of the Neolithic across North-west Europe was a rapid and stochastic affair (Rowley-Conwy Reference Rowley-Conwy2011), and the Dogger Littoral may have formed an exciting staging ground for whatever adaptations, innovations and social tensions comprised the final transition to farming (Garrow & Sturt Reference Garrow and Sturt2011).

Conclusion

The wealth of sedimentological evidence relating to the Storegga tsunami from around the northern North Sea basin makes the lack of archaeological evidence for the event even more curious. It seems reasonable to suggest that the Storegga tsunami must have been catastrophic to those caught within the run-in zone, and the event may have had significant knock-on effects for communities farther inland. Recent advances in palaeotopography, hydrological modelling and, now, the first evidence of the tsunami itself from the southern North Sea (Gaffney et al. Reference Gaffney2020) suggest that the impact of the tsunami would have been contingent upon regional variations in landscape and environment; this may begin to explain the puzzling absence of archaeological evidence.

Ultimately, the Storegga tsunami was neither universally catastrophic, nor was it a final flooding event for the Dogger Bank or the Dogger Littoral. The impact of the tsunami was highly contingent upon landscape dynamics, and the subsequent rise in sea level would have been temporary. Significant areas of the Dogger Littoral, if not also the Archipelago, may have survived well beyond the Storegga tsunami and into the Neolithic, a possibility that contributes to our understanding of the Mesolithic–Neolithic transition in North-west Europe.

Acknowledgements

We thank both Stein Bondevik and Marc Hijma for kindly sharing their work. We acknowledge PGS (https://www.pgs.com/) for provision of data used in this paper, under licence CA-BRAD-001-2017.

Funding statement

The study was supported by European Research Council funding through the European Union's Horizon 2020 research and innovation programme (project 670518 LOST FRONTIERS, https://erc.europa.eu/ https://lostfrontiers.teamapp.com/) and the Estonian Research Council grant (https://www.etag.ee; project PUTJD829).

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.15184/aqy.2020.49

References

Bailey, G., Harff, J. & Sakellariou, D. (ed.). 2017. Under the sea: archaeology and palaeolandscapes of the continental shelf. New York: Springer. https://doi.org/10.1007/978-3-319-53160-1CrossRefGoogle Scholar
Bettinger, R.L., Garvey, R. & Tushingham, S.. 2015. Hunter-gatherers: archaeological and evolutionary theory. New York: Springer. https://doi.org/10.1007/978-1-4899-7581-2CrossRefGoogle Scholar
Blankholm, H.P. 2020. In the wake of the wake: an investigation of the impact of the Storegga tsunami on the human settlement of inner Varangerfjord, northern Norway. Quaternary International 549: 6573. https://doi.org/10.1016/j.quaint.2018.05.050CrossRefGoogle Scholar
Bondevik, S. 2003. Storegga tsunami sand in peat below the Tapes beach ridge at Harøy, western Norway, and its possible relation to an Early Stone Age settlement. Boreas 32: 476–83. https://doi.org/10.1080/03009480310003379CrossRefGoogle Scholar
Bondevik, S. 2019. Tsunami from the Storegga landslide, in Meyers, R.A. (ed.) Encyclopedia of complexity and systems science: 133. Berlin: Springer. https://doi.org/10.1007/978-3-642-27737-5_644-1Google Scholar
Bondevik, S., Svendsen, J.I. & Mangerud, J.. 1998. Distinction between the Storegga tsunami and the Holocene marine transgression in coastal basin deposits of western Norway. Journal of Quaternary Science 13: 529–37. https://doi.org/10.1002/(SICI)1099-1417(1998110)13:6<529::AID-JQS388>3.0.CO;2-13.0.CO;2-1>CrossRefGoogle Scholar
Bondevik, S., Stormo, S.K. & Skjerdal, G.. 2012. Green mosses date the Storegga tsunami to the chilliest decades of the 8.2 ka cold event. Quaternary Science Reviews 45: 16. https://doi.org/10.1016/j.quascirev.2012.04.020CrossRefGoogle Scholar
Bugge, T. 1983. Submarine slides on the Norwegian continental margin with special emphasis on the Storegga area (Publication 110). Trondheim: Continental Shelf Institute, Norway.Google Scholar
Bugge, T., Befring, S., Belderson, R.H., Eidvin, T., Jansen, E., Kenyon, N.H., Holtedahl, H. & Sejrup, H.P.. 1987. A giant three-stage submarine slide off Norway. Geo-Marine letters 7: 191–98. https://doi.org/10.1007/BF02242771CrossRefGoogle Scholar
Burroughs, W.J. 2005. Climate change in prehistory: the end of the reign of chaos. Cambridge: Cambridge University Press. https://doi.org/10.1017/CBO9780511535826CrossRefGoogle Scholar
Cain, G., Goff, J. & McFadgen, B.. 2018. Prehistoric coastal mass burials: did death come in waves? Journal of Archaeological Method and Theory 26: 714–54. https://doi.org/10.1007/s10816-018-9386-yCrossRefGoogle Scholar
Chacón-Barrantes, S., Rangaswami, N. & Mayerle, R.. 2013. Several tsunami scenarios at the North Sea and their consequences at the German Bight. Science of Tsunami Hazards: Journal of Tsunami Society International 32: 828.Google Scholar
Cochard, R. 2011. On the strengths and drawbacks of tsunami-buffer forests. Proceedings of the National Academy of Sciences of the USA 108: 18571–72. https://doi.org/10.1073/pnas.1116156108CrossRefGoogle ScholarPubMed
Cohen, K.M. & Hijma, M.. 2008. Het Rijnmondgebied in het Vroeg-Holoceen: inzichten uit een diepe put bij Blijdorp (Rotterdam). Groondboor & Hamer Nederlandse Geologische Vereniging 62 (3/4): 6471.Google Scholar
Cohen, K.M., Westley, K., Erkens, G., Hijma, M.P. & Weerts, H.J.T.. 2017. The North Sea, in Flemming, N., Harff, J., Moura, D., Burgess, A. & Bailey, G. (ed.) Submerged landscapes of the European continental shelf: Quaternary palaeoenvironments: 147–86. Chichester: Wiley Blackwell. https://doi.org/10.1002/9781118927823.ch7CrossRefGoogle Scholar
Coles, B.J. 1998. Doggerland: a speculative survey. Proceedings of the Prehistoric Society 64: 4581. https://doi.org/10.1017/S0079497X00002176CrossRefGoogle Scholar
Coles, B.J. 1999. Doggerland's loss and the Neolithic, in Coles, B., Coles, J. & Jørgensen, M.S. (ed.) Bog bodies, sacred sites and wetland archaeology (WARP Occasional Paper 12): 5159. Exeter: Wetland Archaeology Research Project.Google Scholar
Corner, G.D., Yevzerov, V.Y., Kolka, V.V. & Møller, J.J.. 1999. Isolation basin stratigraphy and Holocene relative sea-level change at the Norwegian-Russian border north of Nikel, northwest Russia. Boreas 28: 146–66. https://doi.org/10.1111/j.1502-3885.1999.tb00211.xCrossRefGoogle Scholar
Cotterill, C.J., E. Phillips, James, L., Forsberg, C.F., Tjelta, T.I., Carter, G. & Dove, D.. 2017. The evolution of the Dogger Bank, North Sea: a complex history of terrestrial, glacial and marine environmental change. Quaternary Science Reviews 171: 136–53. https://doi.org/10.1016/j.quascirev.2017.07.006CrossRefGoogle Scholar
Dawson, A.G. & Shi, S.. 2000. Tsunami deposits. Pure and Applied Geophysics 157: 875–97. https://doi.org/10.1007/s000240050010CrossRefGoogle Scholar
Dawson, A.G., Long, D. & Smith, D.E.. 1988. The Storegga slides: evidence from eastern Scotland for a possible tsunami. Marine Geology 82: 271–76. https://doi.org/10.1016/0025-3227(88)90146-6CrossRefGoogle Scholar
Dawson, A.G., Smith, D.E. & Long, D.. 1990. Evidence for a tsunami from a Mesolithic site in Inverness, Scotland. Journal of Archaeological Science 17: 509–12. https://doi.org/10.1016/0305-4403(90)90031-YCrossRefGoogle Scholar
Dawson, A.G., Smith, D.E. & Long, D.. 1994. Geomorphological effects of tsunami run-up and backwash. Geomorphology 10: 8394. https://doi.org/10.1016/B978-0-444-82012-9.50010-4CrossRefGoogle Scholar
Dawson, A., Bondevik, S. & Teller, J.T.. 2011. Relative timing of the Storegga submarine slide, methane release, and climate change during the 8.2 ka cold event. The Holocene 21: 1167–71. https://doi.org/10.1177/0959683611400467CrossRefGoogle Scholar
Dawson, A.G., Dawson, S., Bondevik, S., Costa, P.J.M., Hill, J. & Stewart, I.. 2020. Reconciling Storegga tsunami sedimentation patterns with modelled wave heights: a discussion from the Shetland Isles field laboratory. Sedimentology. The Journal of the International Association of Sedimentologists 67: 1344–53. https://doi.org/10.1111/sed.12643Google Scholar
Edwards, K.J. 2004. Palaeoenvironments of the Late Upper Palaeolithic and Mesolithic periods in Scotland and the North Sea area: new work, new thoughts, in Saville, A. (ed.) Mesolithic Scotland and its neighbours: the Early Holocene prehistory of Scotland, its British and Irish context and some Northern European perspectives: 5572. Edinburgh: Society of Antiquaries of Scotland.Google Scholar
Emery, A.R., Hodgson, D.M., Barlow, N.L.M., Carrivick, J.L., Cotterill, C.J., Mellett, C.L. & Booth, A.D.. 2019. Topographic and hydrodynamic controls on barrier retreat and preservation: an example from Dogger Bank, North Sea. Marine Geology 416: 105981. https://doi.org/10.1016/j.margeo.2019.105981CrossRefGoogle Scholar
EMODnet. 2018. Available at: http://www.emodnet.eu (accessed 21 September 2020).Google Scholar
Engel, M., Pilarczyk, J., May, S.M., Brill, D. & Garrett, E. (ed.). 2020. Geological records of tsunamis and other waves. Amsterdam: Elsevier. https://doi.org/10.1016/C2017-0-03458-4Google Scholar
Estévez, J. 2008. Catastrophes or sudden changes: the need to review our time perspective in prehistory, in Buchet, L., Rigeade, C., Séguy, I & Signoli, M. (ed.) Vers une anthropologie des catastrophes: Actes des 9e Journées d'anthropologiques de Valbonne (22–24 mai 2007): 1935. Antibes: APDCA.Google Scholar
Faas, A.J. & Barrios, R.E.. 2015. Applied anthropology of risk, hazards, and disasters. Human Organization 74: 287–95. https://doi.org/10.17730/0018-7259-74.4.287CrossRefGoogle Scholar
Fitch, S., Thomson, K. & Gaffney, V.. 2005. Late Pleistocene and Holocene depositional systems and the palaeo-geography of the Dogger Bank, North Sea. Quaternary Research 64: 185–96. https://doi.org/10.1016/j.yqres.2005.03.007CrossRefGoogle Scholar
Gaffney, V., Thomson, K. & Fitch, S. (ed.). 2007. Mapping Doggerland: the Mesolithic landscapes of the southern North Sea. Oxford: Archaeopress.CrossRefGoogle Scholar
Gaffney, V. et al. 2020. Multi-proxy characterisation of the Storegga tsunami and its impact on the early Holocene landscapes of the southern North Sea. Geosciences 10: 270. https://doi.org/10.3390/geosciences10070270CrossRefGoogle Scholar
Garrow, D. & Sturt, F.. 2011. Grey waters bright with Neolithic argonauts? Maritime connections and the Mesolithic–Neolithic transition within the ‘western seaways’ of Britain, c. 5000–3500 BC. Antiquity 85: 5972. https://doi.org/10.1017/S0003598X00067430CrossRefGoogle Scholar
Gearey, B.R., Hopla, E.-J., Boomer, I., Smith, D., Marshall, P., Fitch, S., Griffiths, S. & Tappin, D.R.. 2017. Multi-proxy palaeoecological approaches to submerged landscapes: a case study from ‘Doggerland’, in the southern North Sea, in Williams, M., Hill, T., Boomer, I. & Wilkinson, I.P. (ed.) The archaeological and forensic applications of microfossils: a deeper understanding of human history: 3553. London: Geological Society. https://doi.org/10.1144/TMS7.3Google Scholar
Goff, J., Chagué-Goff, C., Nichol, S., Jaffe, B. & Dominey-Howes, D.. 2012. Progress in palaeotsunami research. Sedimentary Geology 243–244: 7088. https://doi.org/10.1016/j.sedgeo.2011.11.002CrossRefGoogle Scholar
Goff, J., Terry, J.P., Chagué-Goff, C. & Goto, K.. 2014. What is a mega-tsunami? Marine Geology 358: 1217. https://doi.org/10.1016/j.margeo.2014.03.013CrossRefGoogle Scholar
Haflidason, H., Lien, R., Sjerup, H.-P., Forsberg, C.F. & Bryn, P.K.. 2005. The dating and morphometry of the Storegga Slide. Marine and Petroleum Geology 22: 123–36. https://doi.org/10.1016/B978-0-08-044694-3.50014-7CrossRefGoogle Scholar
Hijma, M. 2009. From river valley to estuary: the Early–Mid Holocene transgression of the Rhine-Meuse valley, the Netherlands (Netherlands Geographical Studies 389). Utrecht: Koninklijk Nederlands Aardrijkskundig Genootschap.Google Scholar
Hijma, M.P. & Cohen, K.M.. 2010. Timing and magnitude of the sea-level jump preluding the 8200 yr event. Geology 38: 275–78. https://doi.org/10.1130/G30439.1CrossRefGoogle Scholar
Hijma, M.P. & Cohen, K.M.. 2019. Holocene sea-level database for the Rhine-Meuse Delta, the Netherlands: implications for the pre-8.2 ka sea-level jump. Quaternary Science Reviews 214: 6886. https://doi.org/10.1016/j.quascirev.2019.05.001CrossRefGoogle Scholar
Hill, J., Collins, G.S., Avdis, A., Kramer, S.C. & Piggott, M.D.. 2014. How does multiscale modelling and inclusion of realistic palaeobathymetry affect numerical simulation of the Storegga Slide tsunami? Ocean Modelling 83: 1125. https://doi.org/10.1016/j.ocemod.2014.08.007CrossRefGoogle Scholar
Hill, J., Avdis, A., Mouradian, S., Collins, G. & Piggott, M.. 2017. Was Doggerland catastrophically flooded by the Mesolithic Storegga tsunami? 118. Available at: arvix.org/abs/1707.05593 (accessed 21 September 2020).Google Scholar
Kulkarni, R., Zimmerman, N., Lanckriet, T. & Breugem, A.. 2017. Inundation risk due to a landslide-generated tsunami in the North Sea, in Dorfmann, C. & Zenz, G. (ed.) Proceedings of the 24th TELEMAC-MASCARET User Conference, 17–20 October 2017, Graz, Austria: 2329. Graz: Verlag der Technischen Universität Graz.Google Scholar
Leary, J. 2015. The remembered land: surviving sea-level rise after the last Ice Age. Debates in archaeology. London: Bloomsbury.Google Scholar
Long, D. 2018. Cataloguing tsunami events in the UK, in Scourse, E.M., Chapman, N.A., Tappin, D.R. & Wallis, S.R. (ed.) Tsunamis: geology, hazards and risks (Geological Society Special Publication 456): 143–65. London: Geological Society. https://doi.org/10.1144/SP456.10Google Scholar
Long, D., Smith, D.E. & Dawson, A.G.. 1989a. A Holocene tsunami deposit in eastern Scotland. Journal of Quaternary Science 4: 6166. https://doi.org/10.1002/jqs.3390040107CrossRefGoogle Scholar
Long, D., Dawson, A.G. & Smith, D.E.. 1989b. Tsunami risk in North-western Europe: a Holocene example. Terra Nova 1: 532–37. https://doi.org/10.1111/j.1365-3121.1989.tb00429.xCrossRefGoogle Scholar
Lowe, D.J. & de Lange, W.P.. 2000. Volcano-meteorological tsunamis, the c. 200 Taupo eruption (New Zealand) and the possibility of a global tsunami. The Holocene 10: 401407. https://doi.org/10.1191/095968300670392643CrossRefGoogle Scholar
McFadgen, B. 2007. Hostile shores: catastrophic events in prehistoric New Zealand and their impact on Maori coastal communities. Auckland: Auckland University Press.Google Scholar
Moe Astrup, P. 2018. Sea-level change in Mesolithic Southern Scandinavia: long- and short-term effects on society and the environment. Aarhus: Aarhus University Press.Google Scholar
National Oceanic and Atmospheric Administration. 2009. Bathymetric data viewer. Available at: https://maps.ngdc.noaa.gov/viewers/bathymetry (accessed 21 September 2020).Google Scholar
Oliver-Smith, A. 1996. Anthropological research on hazards and disasters. Annual Review of Anthropology 25: 303–28. https://doi.org/10.1146/annurev.anthro.25.1.303CrossRefGoogle Scholar
Peeters, H.P., Murphy, P. & Flemming, N. (ed.). 2009. North Sea prehistory research and management framework (NSPRMF). Amersfoort: Rijksdienst voor het Cultureel Erfgoed & English Heritage.Google Scholar
Pingree, R.D. & Griffiths, D.K. 1982. Tidal friction and the diurnal tides on the North-west European shelf. Journal of the Marine Biological Association of the United Kingdom 62: 577–93. https://doi.org/10.1017/S0025315400019767CrossRefGoogle Scholar
Rowley-Conwy, P. 2011. Westward ho! The spread of agriculture from Central Europe to the Atlantic. Current Anthropology 52: 431–51.CrossRefGoogle Scholar
Rydgren, K. & Bondevik, S.. 2015. Moss growth patterns and timing of human exposure to a Mesolithic tsunami in the North Atlantic. Geology 43: 111–14. https://doi.org/10.1130/G36278.1CrossRefGoogle Scholar
Seneviratne, S.I. et al. 2012. Changes in climate extremes and their impacts on the natural physical environment, in Field, C.B. et al. (ed.) A special report of Working Groups I and II of the Intergovernmental Panel on Climate Change (IPCC): 109230. Cambridge: Cambridge University Press.Google Scholar
Shennan, I., Bradley, S.L. & Edwards, R.. 2018. Relative sea-level changes and crustal movements in Britain and Ireland since the Last Glacial Maximum. Quaternary Science Reviews 188: 143–59. https://doi.org/10.1016/j.quascirev.2018.03.031CrossRefGoogle Scholar
Shi, S. & Smith, D.E.. 2003. Coastal tsunami geomorphological impacts and sedimentation processes: case studies of modern and prehistorical events. Proceedings of the International Conference on Estuaries and Coasts: ICEC-2003, November 9–11, 2003, Hangzhou, China: 189–98. Zhejiang: Zhejiang University Press.Google Scholar
Smith, D.E. et al. 2004. The Holocene Storegga Slide tsunami in the United Kingdom. Quaternary Science Reviews 23: 2291–21. https://doi.org/10.1016/j.quascirev.2004.04.001CrossRefGoogle Scholar
Spencer, T., Brooks, S.M., Möller, I. & Evans, B.R.. 2014. Where local matters: impacts of a major North Sea storm surge. Eos 95: 269–70. https://doi.org/10.1002/2014EO300002CrossRefGoogle Scholar
Sturt, F., Flemming, N.C., Carabias, D., Jöns, H. & Adams, J.. 2018. The next frontiers in research on submerged prehistoric sites and landscapes on the continental shelf. Proceedings of the Geologist's Association 129: 654–83. https://doi.org/10.1016/j.pgeola.2018.04.008CrossRefGoogle Scholar
Sugawara, D., Minoura, K. & Imamura, F.. 2008. Tsunamis and tsunami sedimentology, in Shiki, T., Tsuji, Y., Yamazaki, T. & Minoura, K. (ed.) Tsunamiites: features and implications: 949. Oxford: Elsevier. https://doi.org/10.1016/B978-0-444-51552-0.00003-5Google Scholar
Törnqvist, T. & Hijma, M.P.. 2012. Links between Early Holocene ice-sheet decay, sea-level rise and abrupt climate change. Nature Geoscience: 601606. https://doi.org/10.1038/ngeo1536CrossRefGoogle Scholar
Torrence, R. & Grattan, J.. 2002. The archaeology of disasters: past and future trends, in Torrence, R. & Grattan, J. (ed.) Natural disasters and cultural change: 118. London: Routledge. https://doi.org/10.4324/9780203279533CrossRefGoogle Scholar
Waddington, C. & Wicks, K.. 2017. Resilience or wipe out? Evaluating the convergent impacts of the 8.2 ka event and Storegga tsunami on Mesolithic of northeast Britain. Journal of Archaeological Science: Reports 14: 692714. https://doi.org/10.1016/j.jasrep.2017.04.015Google Scholar
Weninger, B. et al. 2008. The catastrophic final flooding of Doggerland by the Storegga Slide tsunami. Documenta Praehistorica 35: 124. https://doi.org/10.4312/dp.35.1CrossRefGoogle Scholar
Yeh, H. & Li, W.. 2008. Tsunami scour and sedimentation, in Sekiguchi, H. (ed.) Proceedings of the 4th International Conference on Scour and Erosion (ICSE-4), November 5–7, 2008, Tokyo, Japan: 95106. Tokyo: The Japanese Geotechnical Society.Google Scholar
Figure 0

Figure 1. a) Map showing the Storegga Slide and sites where tsunami deposits have been found; b) ‘Europe's Lost Frontiers’ project coring locations, with ELF001A highlighted (topography: National Oceanic and Atmospheric Administration 2009; bathymetry: EMODnet 2018; image by M. Muru).

Figure 1

Figure 2. North Sea coastline reconstructions for: a) Doggerland c. 10 000 cal BP; b) Dogger Archipelago c. 9000 cal BP; c) Dogger Archipelago c. 8200 cal BP; d) Dogger Littoral c. 7000 cal BP (image by M. Muru).

Figure 2

Figure 3. Stratigraphic units in core ELF001A (for full details, see Figure S1 & Table S2 in the online supplementary material; image by M. Muru & M. Bates).

Figure 3

Figure 4. Model showing the Storegga tsunami and run-up around the western sector of the southern North Sea at 8150 cal BP (image by M. Muru).

Supplementary material: PDF

Walker et al. supplementary material

Walker et al. supplementary material

Download Walker et al. supplementary material(PDF)
PDF 692.3 KB