Geographical and soil background

The River Kennet is a small upland chalk river with a catchment of 1138 km² which flows from a north-west direction eastwards to Marlborough and on to the River Thames near Reading over a length of c. 86 km (Whitehead & Edmunds Reference Whitehead and Edmunds2012) (Fig. 1). The upper reach from just to the north of Avebury to Marlborough over a distance of c. 28 km is generally a small channel, as a stream to the north-west of Avebury, widening southwards towards Silbury Hill and then eastwards towards Marlborough. It has a relatively narrow floodplain varying between c. 50 m and 150 m in its upper part through to c. 150–200 m downstream. It is a highly localised small catchment of about 25 km² immediately and demonstrably interlinked with the monuments of the Avebury landscape. Consequently, it creates a sensitive sediment receptor with which to study prehistoric landscape impact and changes associated with this monumental landscape throughout the Holocene.

The present-day soils of the Avebury landscape include calcareous alluvial gley soils on the floodplains; typical brown calcareous earths on the clay-rich Lower Chalk, gravels, and Coombe Rock; common rendzinas on the Middle and Lower Chalk downland slopes, under both arable and grassland; and, less commonly, argillic brown earths in a few areas on Clay-with-Flints (Barron Reference Barron1976; Findlay et al. Reference Findlay, Colborne, Cope, Harrod, Hogan and Staines1984). These soils are all alkaline, with the possible exception of the argillic brown earths, and are situated on Upper, Middle, and Lower Chalk as well as periglacial deposits formed of mixtures of cryoturbated and soliflucted chalk, flint, and loess (known as Coombe Rock), and river gravels composed of flint and chalk pebbles. Alkaline groundwater emerges from numerous springs, mainly at the boundary of the more permeable Middle Chalk and the less permeable clay-rich Lower Chalk, such as along the southern edge of Waden Hill below the modern A4 road scarp and the western valley/Y-fork of the Kennet (the Oslip stream) beyond Avebury Trusloe to the north-west.

A CHRONOSTRATIGRAPHIC DEPOSIT MODEL FOR THE UPPER KENNET VALLEY

Alluvial deposit sequences were present along the whole length of the upper River Kennet valley from north-west of Avebury (Zone A) to North Farm, West Overton (Zone E). From immediately west of Avebury to North Farm (Zones B–E), the alluvial deposit sequence showed a remarkable cross-correlation, in both the characteristics of the wider sediment units and their chronological relationships. The field data has been necessarily detailed above and in Appendices S1–S5 but is essential to construct true chronostratigraphic deposit models of the wider floodplain reaches, especially when there is an intimate relationship between the river system and prehistoric monumental complexes. However, to simplify this dense data capture, the alluvial zones, key alluvial stratigraphic units, their key sedimentary characteristics, OSL dates (Tables 3 & S2), and associated interpretations are presented in a concise chronostratigraphic deposit model (cf. Carey et al. Reference Carey, Howard, Corcoran, Knight and Heathcote2019), which has correlated equivalent sediment units across the valley based on their physical characteristics (Tables 5, S1, & S8).

Table 5.

A summary chronostratigraphic model for the upper Kennet valley

From this model different phases of alluviation are observable that are associated with different phases of landscape utilisation and consequent impacts, with resultant changes in floodplain and channel morphology. The upper Kennet floodplain at both North Farm and Butler’s Field contains areas of localised low topography formed during the Pleistocene which have acted as sediment traps for the first phase of channel bed alluviation in both the late Pleistocene and Early Holocene (pre-Neolithic). The composition of the fluvial units infilling these localised low point depressions is distinct, with high clay and carbonate contents and the presence of chalk and flint pebbles, forming through water flowing into and pooling in these depressions. Abundant areas of exposed chalk in other parts of the floodplain have facilitated bedrock dissolution through a wide, shallow channel, with some implied areas of braid plain. The relatively high clay content is interpreted as indicative of the differential erosion of soils, resulting from rain-splash, low energy erosion of open but relatively undisturbed topsoils, exaggerating the clay component of the early alluvial deposits. Within the topographic low point depressions, some of the channel bedload has been redeposited (ie, chalk/flint pebbles) alongside reprecipitation of calcite and the deposition of clay, through standing water.

The second phase from the Early Neolithic through to the Bronze Age was clearly critical within the development of the Avebury landscape. This period saw the creation of numerous monuments that provide this landscape with its special character, starting with long barrows (earthen and chambered) and enclosures in the 4th millennium bc and likely the earliest megalithic settings. Subsequently this was followed seemingly by a hiatus, then the creation from the mid-3rd millennium of the greatest monuments, among them Avebury, its Avenues, stone and wooden circles, the West Kennet palisade enclosures, and the gigantic mound of Silbury Hill. Even the region’s round barrow cemeteries represent a considerable investment in labour. Unsurprisingly, it has been previously hypothesised that there had been widespread clearance of the post-glacial woodland at this time, facilitating monumentalisation of already cleared ancestral spaces within the landscape (Evans et al. Reference Evans, Limbrey, Mate and Mount1993; Whittle et al. Reference Whittle, Pollard and Grigson1999). Therefore, understanding the signature of human induced alluviation in the Neolithic–Early Bronze Age is critical in understanding the human–environment context of landscape, land use and impact, and the context of monument construction and use. Those signatures could include soil and vegetation disturbance during the extraction and movement of stones (eg, in excess of 700 megalithic blocks: Gillings & Pollard Reference Gillings and Pollard2016), the clearance and breaking of ground for monument building, the felling of trees to provide timber for The Sanctuary and West Kennet palisade enclosures, estimated at c. 15 ha of mature woodland by Whittle (Reference Whittle1997, 154), and soil erosion through attendant gatherings of people and animals en masse.

It is therefore striking, and somewhat unexpected, that the signals of human induced alluviation caused by landscape impacts throughout this period are slight. Within the localised topographic low point depressions across the floodplain water continued to flow and deposited calcite rich sediments in a single channel. In many respects, this corroborates the previously modelled palaeo-hydrological study of river flow north of Silbury Hill to at least Avebury henge, rather than a winterbourne channel (Whitehead & Edmunds Reference Whitehead and Edmunds2012). However, within these sediments there are increasing fine to coarse silt and very fine quartz sand (or loessic) components that signal a degree of human induced soil disturbance of soil surfaces within the catchment and limited wind and rain-splash erosion of soil material. This signal started by about 4000 bc and continued to at least the later Bronze Age between about 1330 and 870 bc (defined from North Farm Test Pit 1) over a period of c. 3000 years. The thickness of this second phase of alluvium deposited in this timeframe is relatively shallow (<0.4 m) and it is not widespread as it only forms within the valley floor depressions and does not overspill to other areas of the floodplain.

Considered together, these first two phases of alluviation must reflect slow, low volume and low velocity erosion in this landscape. This strongly suggests a very stable hinterland, whether under woodland or grassland, with minimal interference through clearance, agriculture, and erosion. The anthropogenic component in the second phase of alluviation during this critical timeframe is interpreted as representing relatively small scale (in a catchment context) landscape disturbance. This is certainly not a model of widespread woodland clearance and derived soil erosion caused through extensive farming on the valley slopes in the Neolithic and Bronze Age. The rate and volume of anthropogenically driven alluviation at this time is more commensurate with small scale soil disturbance, whether this was woodland clearance or simply soil disturbance within grasslands, potentially even at the scale of monument construction (eg, Avebury and Silbury Hill). These enormous prehistoric monuments are situated very close, or directly adjacent, to the river channel, both at the floodplain margins and as such demonstrate a direct connection between the river and these monuments (cf. Richards Reference Richards1996). It is tempting, but speculative, to see the anthropogenic alluviation signature visible in this second phase of alluviation as a product of such localised monument construction and associated soil disturbance, rather than widespread agricultural disturbance and soil erosion.

Whatever is the driver for this minor anthropogenic driven alluviation between the Early Neolithic to Middle–Late Bronze Age, it is clear that the rate of alluvial deposition significantly increased from the Late Bronze–Early Iron Age. It is at the time that more sustained agrarian landscapes developed around the area of the former monument complex (Pollard & Reynolds Reference Pollard and Reynolds2002). The low point depressions on the floodplain floor had largely infilled by this period and areas of slightly higher topography within the valley bottom that previously had developed soils became inundated and buried by a third phase of alluviation. The alluvium is now defined by eroded soil material composed mainly of the fine–coarse silt and very fine quartz sand fractions, probably derived from inherent loessic soil components from the catchment.

This more widespread and increased intensity of alluviation was probably the product of anthropogenically driven soil erosion on the valley sides from the Middle–Late Bronze Age/Early Iron Age onwards. This implies the expansion of cultivated, or at least disturbed, land into areas that were previously undisturbed. Nonetheless, this use of the landscape through this time period unequivocally defined a landscape that was largely open grassland, not woodland. It would not have been possible to construct so many interconnected monuments within this landscape without clearing areas of woodland on a larger scale. Of course, the signature of alluviation does not provide a direct palaeo-environmental context for each locale of monument construction but it does provide a wider catchment view.

This is significant, as a predominantly grassland landscape would have been distinct to the more wooded river valleys off the chalk uplands (eg, the Greensand vales, such as in the Vale of Pewsey; Evans Reference Evans1972, 274–7; Leary & Field Reference Leary and Field2012) and this has a potential interpretative value in explaining monumentalisation in the Avebury area. Either way, the signature of the fourth phase of alluviation from the Late Bronze Age–Early Iron Age continues throughout the Roman period and into the early medieval period. The rate of anthropogenically driven alluviation from the Late Bronze Age/Early Iron Age substantively increased, providing deeper and more widespread alluvial deposits across the valley floor. Throughout this time scale the level of calcite steadily decreased, defining a floodplain that was increasingly infilling with fine (silt and clay) alluvial sediments, slowly constraining the channel over time until it became a single thread channel, meandering across the floodplain.

By the later medieval period there is a very low carbonate content in the alluvium and the overall particle size has decreased, producing a valley wide, fine grained, clay rich alluvium in the fifth and final phase of alluviation. It comprises a very dark brown to dark greyish brown, silty clay loam with a very well developed columnar blocky ped structure. This deposit is very humic and probably topsoil derived from the catchment upstream and upslope and is associated with the seasonal overbank flooding of long-term pasture. It most probably developed hand-in-hand with the post-late 16th century ad construction of the embanked water catchment pond system as observed in Butler’s Field (McOmish et al. Reference McOmish, Riley, Field, Lewis, Brown, Field and McOmish2005; Pollard et al. Reference Pollard, Gillings and Chan2018a) and is reflecting topsoil erosion associated with wide-scale arable agriculture in the immediate catchment. This alluvial unit continues into the post-medieval period, defining a floodplain that had infilled and choked up with nearly 2500 years of anthropogenically induced alluvium. Unfortunately, the available geochronological data lacks the resolution to define changes in the rate of alluvial deposition across the floodplain in the Roman and later periods and it is currently not clear if there are periods of higher or lower alluvial deposition during the post-Roman to post-medieval timeframe.

NEOLITHIC STABILITY AND LATE BRONZE AGE/IRON AGE DISTURBANCE

The alluvial sediment record provides a clear model of landscape impacts and, to some extent land-use, throughout the Holocene (Tables 5 & S8). However, this model substantially contradicts previous studies that interpreted much larger impacts by prehistoric societies on these environments (eg, Evans et al. Reference Evans, Pitts and Williams1985; Reference Evans, Limbrey, Mate and Mount1993). The new geochronological deposit model presented here stands in stark contrast to the magnificent scale of Neolithic and Bronze Age monuments that characterise this outstanding prehistoric landscape.

Early Holocene and Neolithic–Bronze Age landscape impacts through soil erosion and subsequent alluviation are detectable in the upper Kennet valley but only from channel bed deposits and limited soil erosion accumulating as alluvium within localised floodplain depressions. These deposits most probably represent low-level landscape impacts across the Neolithic–Early Bronze Age timeframes. The major alluviation in the valley did not start in earnest until the Late Bronze Age/Early Iron Age and provides palaeo-environmental context for this area. However, it is a dataset that also provides an explanation for understanding human activity in the periods of prehistory when alluviation was not present or slight as in the Neolithic and Early Bronze Age.

The palaeo-environmental context from the soil and sedimentary records in the upper Kennet valley is clear. The majority of the Avebury landscape was relatively stable and ostensibly open grassland on rendzina soils by the Neolithic period. There is no strong evidence for intensive or extensive landscape disturbance in the sediment record during the construction of long barrows, henges, avenues, and enclosures in the Neolithic, nor associated with the construction of barrows in the Early Bronze Age within the Avebury World Heritage landscape. Nonetheless, there were undoubtedly some intense impacts taking place in the middle and third quarter of the 3rd millennium bc in terms of monument construction which have not left substantial fingerprints in the floodplain alluvial record nor in valley bottom colluvial accumulations. This suggests that these events were spatially localised and relatively not disruptive of the wider landscape, over ill-defined and variable timeframes.

Put simply, large areas of woodland did not need to be cleared with associated soil disturbance in order to facilitate monument construction, although structures such as the West Kennet palisade enclosures would have required large areas of woodland to be felled (Whittle Reference Whittle1997, 154) and, likewise, extensive areas of turf and chalk substrate would have been required for the construction of sites such as Silbury Hill (Leary et al. Reference Leary, Field and Campbell2013). Nonetheless, the areas affected by human activities are still relatively localised when considered on a catchment scale. Indeed, the insect assemblages in the Late Neolithic levels at Silbury Hill are dominated by open country species of herb-rich, light to medium grazed, well drained, unimproved grassland and, significantly, no specific fauna that could be linked to bare to disturbed ground and only 0.5% of the Coleoptera were associated with trees and woodland (Robinson Reference Robinson1997; Reference Robinson2011). In addition, the molluscan assemblages beneath the Early Neolithic long barrows in the Avebury landscape, such as West Kennet, and in the turf stack beneath Late Neolithic Silbury Hill ostensibly exhibited open grassland on thin rendzina soils succeeding a more shaded environment (Evans Reference Evans1972, 263–7; Leary et al. Reference Leary, Field and Campbell2013), with the only clear indication of woodland fauna being present observed in a much earlier subsoil hollow beneath the henge bank of Avebury in the Vatchers’ excavations (Evans Reference Evans1972, 268–73; Vatcher & Vatcher Reference Vatcher and Vatcher1976). These palaeo-environmental aspects will be developed in the succeeding companion paper to this (French et al. in prep.).

Whilst this evidence provides a landscape context, perhaps this also helps to interpret the remarkable concentration of Neolithic and Bronze Age monuments in the Avebury landscape. It is known that earlier monuments, such as long barrows and cursus monuments, provide a focus for later aggrandisation and monumentalisation, but why are these early Neolithic monuments built within these specific landscapes to start with (cf. Pollard Reference Pollard2012)? Maybe it was the already largely open nature of this landscape, with increased visibility, extensive horizons, and skyscapes, that provided an area suitable for both settlement and the construction of monuments, and/or an ancestral or spiritual realm, which were different to other nearby off-chalk plateaux environments? Rather than monuments being constructed within woodland clearings, the more substantially open landscape provided a setting suitable for monument construction with areas of sarsen spreads easily visible. In other words, the monuments did not create the landscape but the landscape enabled the creation of the monuments. Certainly, several other major chalkland landscapes in southern England that have substantive monumentalisation, such as Stonehenge/Durrington Walls, Dorchester, and Cranborne Chase also revealed a similar, largely open, grassland aspect to their Neolithic and Bronze Age environments (Smith Reference Smith1997; French et al. Reference French, Lewis, Allen, Green, Scaife and Gardiner2007; Reference French, Scaife and Allen2012). Moreover, these landscapes may be part of longer term, patchy open landscape trajectories and that may have had greater longevity than hitherto expected (cf. Svenning Reference Svenning2002; Whitehouse & Smith Reference Whitehouse and Smith2010; Robinson Reference Robinson2014).

Ideas of semi-sedentary lives in the early Neolithic and more mobile transhumant lives in the later Neolithic have been postulated (Bradley Reference Bradley1998; Thomas Reference Thomas1999; Leary & Kador Reference Leary and Kador2016). It is also clear that there is a wider reduction of cereal growth in the middle and later Neolithic (Stevens & Fuller Reference Stevens and Fuller2015). However, is there a signature of small scale horticulture on some of the valley sides in the Neolithic at Avebury? The answer is certainly not on a scale that has caused deposition of either deep or widespread colluvial or alluvial deposits in this landscape. As such, the alluvial archive record represents a landscape of wider sustained stability and only small scale localised disturbance despite a number of Neolithic lithic scatters and spreads seemingly being suggestive of an active and very much lived-in landscape. The nature of the alluvial record might not be such a juxtaposition to the monumental record as it first appears. Maybe the archaeological and geoarchaeological records tell the same story. It was a landscape that was certainly visited, used, and lived in, but may not have been cultivated in any great intensity during the 4th through to the mid-2nd millennium bc. But to maintain this landscape of ostensibly open grassland, it would have had to have been grazed and managed at a reasonable intensity. For example, dynamic ecosystem modelling of this aspect in the upper Allen valley by Samarasundera (Reference Samarasundera2007, 199–205) has suggested that it could have required as few as 2.5 livestock (ie sheep and cattle) per hectare to keep the downland as grassland and free of woodland regeneration.

Perhaps, also, the extent and scale of settlement presence across the region during the Neolithic has been over-estimated by the LwM team, and especially during the latter part of that period. Consequently, this must feed into how to think about the nature of environmental impacts. This is an observation that comes out of the various lithic scatter excavations undertaken during the LwM project. Some, such as the Foot of Avebury Down (FAD) initially looked like they represented a very dense and sustained Neolithic presence but, following analysis of the lithic assemblage, it was clear that much of the flintwork was of probable Middle Bronze Age date (B. Chan, pers. comm.; Pollard et al. Reference Pollard, Gillings and Chan2017). There are still Early, Middle, and Late Neolithic components that can be drawn out of this site but they are quite localised and do not constitute a dense and sustained presence. Likewise, on Folly Hill west of Silbury Hill, there is a ‘background’ of Early Neolithic lithic material but much is again of probable Middle Bronze Age date (Pollard et al. Reference Pollard, Gillings and Chan2020a). In contrast, sites like the Middle Neolithic occupation on the West Kennet Avenue may be exceptional in terms of representing a more sustained presence (Gillings et al. Reference Gillings, Allen, French, Cleal, Snashall, Pike and Pollard2015a; Reference Gillings, Pollard, Allen, Pike, Snashall, Cleal and French2015b), potentially linked to gathering for the building of the earliest phase settings and earthwork at Avebury.

The one location in the region where settlement is well attested is at the causewayed enclosure on the summit and southern slopes of Windmill Hill (Whittle et al. Reference Whittle, Pollard and Grigson1999). This may be the principal settlement locale throughout the Neolithic. Although interpretation of the site as a settlement focus might run counter to current views of causewayed enclosures as gathering points for communities and sites of ceremony (through equation with its monumental status; Bradley Reference Bradley1998; Edmonds Reference Edmonds1999; Whittle et al. Reference Whittle, Healy and Bayliss2011), the material signatures there conform closely to what we should expect of settlement activity at scale (ie large and varied numbers of tools and, from the enclosure, querns, hearth debris, etc.; Pollard Reference Pollard2021).

It is also worth expanding our focus outwards and considering how some of the environmental impacts of both monument building and dwelling might be more distributed, extending in part beyond the region. Accepting a degree of settlement mobility, perhaps especially in the Middle and Late Neolithic, it follows that communities were spending some of their time, seasonally or at greater intervals, outside the Avebury region. In the case of monuments, we have Whittle’s observation that the straight-grown timbers used in the West Kennet palisades were most likely brought in, perhaps from Clay-with-Flints areas c. 4+ km to the east (Whittle Reference Whittle1997, 154). In this case, the environmental impact of monument construction may have taken place elsewhere. There is also the situation during the Late Neolithic, again with the West Kennet palisade enclosures, where isotope evidence shows a number of the animals consumed at the site were raised off the chalk, some at a great distance (Evans et al. Reference Evans, Parker Pearson, Madgwick, Sloane and Albarella2019; Madgwick et al. Reference Madgwick, Lamb, Sloane, Nederbraat, Albarella, Parker Pearson and Evans2019), and the material record (ie cores likely from East Anglia and granodiorite from the north-east) also supports the idea of people and animals coming into the region for monument building and ceremony. It may be that the total environmental impact was greater than that seen in the Avebury World Heritage landscape per se, being both more temporary and ephemeral (cf. Robinson Reference Robinson2014) and distributed across a range of locations on a wider inter-regional scale.