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What's in the pots? Identifying Possible Extensification in Roman Britain Through Analysis of Organic Residues in Pottery

Published online by Cambridge University Press:  04 September 2023

C.E. Greenwood ,
L.J.E. Cramp  and
T. Hodos
C.E. Greenwood
Affiliation:
Museum of North Craven Life caitlingreenwood57@gmail.com
L.J.E. Cramp
Affiliation:
University of Bristol lucy.cramp@bristol.ac.uk
T. Hodos
Affiliation:
University of Bristol t.hodos@bristol.ac.uk
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Abstract

This study examined absorbed organic residues in pottery to assess differences in subsistence practices in Roman Britain. Through this approach, we investigated foodways at a major urban site and a range of small towns, villas and farmsteads within its hinterland. The study revealed that consumption at Cirencester differed remarkably to consumption at other sites in the surrounding hinterland, with a greater contribution from pigs and/or chickens. Dairy products were a key contributor to the diet at rural sites, including a high-status villa. We contend that both findings are the result of extensification of food production. Thus, we show how reconstructing broad culinary patterns can reveal possible responses of inhabitants to the challenges of feeding the increasing population of Roman Britain.

Keywords

organic residue analysisfoodagricultureanimal husbandryextensificationCirencesterpottery
Type
Articles
Information
Britannia , Volume 54 , November 2023 , pp. 137 - 165
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Society for the Promotion of Roman Studies

INTRODUCTION

Scholars of Roman Britain have long been interested in the relationship between rural and urban settlements. Cities have been characterised as ‘alien’,Footnote 1 bearing no relation to other settlement types, especially in the early Roman period. After the end of the first century a.d., they are also viewed as centres of market redistribution, at least for exotic foodstuffs.Footnote 2 More traditionally, towns have been classed as ‘consumers’ while rural settlements were ‘producers’.Footnote 3

The integration of late pre-Roman Iron Age societies into the Roman economy is also of great interest. Although late Iron Age societies were clearly able to produce a surplus,Footnote 4 this process was undoubtedly formalised under Roman rule into a system of taxation,Footnote 5 even if the minutiae are lost to us. At the same time, the population of the island grew rapidly thanks to the arrival of the Roman army and an influx of merchants to newly founded cities.Footnote 6 By the end of the second century a.d., twice the number of settlements were recorded than for the late Iron Age.Footnote 7 All these people needed to be fed, and a surplus generated to supply the state. At the same time, the proportion of people working the land probably decreased as urban populations grew. The effects of this economic pressure are seen in many aspects of rural life: more land was taken under arable cultivation,Footnote 8 using newly imported heavy ploughshares.Footnote 9 Emphasis on sheep declined in favour of cattle, as urban meat markets boomedFootnote 10 and all three major domesticates, cattle, sheep and pigs, increased in size. Lodwick and Allen see these practices as ‘extensification’: the production of more food for the same labour input through increasing the area of land under cultivation, increasing animal and herd sizes and by decreasing labour-intensive activities such as manuring or dairy farming.Footnote 11 However, this general picture masks considerable variation in subsistence practices across Roman Britain. Were dairying practices abandoned by all farming people, in favour of cattle destined for the urban meat market? Were the inhabitants of cities simply consumers, drawing in all produce from their hinterlands and further afield?

The analysis of absorbed residues from large assemblages of pottery used in Roman Britain offers a direct way to compare everyday dietary practices over time and space, and in so doing offers an alternative approach to address these questions. This study investigated organic residues preserved in hundreds of sherds from cooking jars (rather than specialist or unusual forms) from a range of settlement types within a single region and spanning five centuries (100 b.c.–a.d. 400). This enabled examination of both variability between subsistence practices at different contemporaneous and connected site types operating within a landscape, as well as consideration of how subsistence strategies continued or emerged in response to the changing social and economic pressures of the Roman world over half a millennium.

USING ORGANIC RESIDUE ANALYSIS TO UNDERSTAND ROMAN FOODWAYS

Organic residue analysis is a powerful approach that provides direct evidence for vessel use through extraction and analysis of absorbed lipid residues surviving in the fabric of unglazed pots.Footnote 12 Recent experiments indicate that absorbed residues accumulate throughout the use-life of the pot.Footnote 13 Residues therefore represent a palimpsest of cooking incidents, not the first or last uses of the vessel. Thus far, organic residue analysis has been applied predominantly to prehistoric pottery, tracing the emergence and spread of specific key commodities, for example, dairy products,Footnote 14 aquatic resourcesFootnote 15 and bee products.Footnote 16 In so doing, it has been possible to trace major shifts in ancient foodways, for example the earliest evidence for dairying activity in the Near East,Footnote 17 northwestern EuropeFootnote 18 and Saharan Africa.Footnote 19

This approach is based on the concept of detecting unique biomarkers, or suites of biomarkers, that can be related back to the signature of the original resource(s) that were processed in the pots.Footnote 20 The scope for the identification of different products depends on the presence of diagnostic finger-prints in the original source, and the survival of this finger-print or its degradation products in archaeological conditions and over archaeological timescales. While some surviving fingerprints can be relatively broad in terms of classification (e.g. the survival of characteristic saturated fatty acids from animal products), combining this approach with the analysis of the stable carbon isotope signature of individual compounds can lend further specificity, in this instance, allowing further classification of animal fats as from ruminant or non-ruminant species, and within the former, dairy fats from carcass fats.Footnote 21 Aquatic fats from marine or freshwater sources can also be recognised.Footnote 22 Other resources such as resins and gum-resins, insect waxes (beeswax) and leafy plants can also be determined.Footnote 23 Plant oils are characterised by high prevalence of unsaturated fatty acids which degrade rapidly and do not usually survive in high abundance; it is important to note that although olive oil contains a high abundance of oleic acid (C18:1 cis-9), this is both non-specific to this source and unlikely to survive archaeologically, more often reflecting a source of contamination when identified in high abundance.Footnote 24 Likewise highly water-soluble biomarkers such as tartaric and succinic acid (so-called ‘wine markers’) will be readily washed out of pottery during deposition.Footnote 25

The British Iron Age has been subject to relatively extensive organic residue analysis, as part of a wider study into dairying in British prehistory. Copley et al. conducted residue analysis on 237 sherds from four sites dating to the Iron Age.Footnote 26 Between 39 and 71 per cent of extracted residues from these sites were identified as milk fats. There was no specific vessel associated with dairy-product processing. Instead, dairy fats tended to be associated with the most commonly used vessel form on each site. Therefore, at Maiden Castle, where jars predominated, dairy fats were most commonly found in jars, while at Danebury, ‘saucepan pots’ were the most common vessel form, and dairy fats were most commonly identified in these vessels. Copley et al. concluded that dairy products were an extremely important commodity to Iron Age populations.

A very small study, examining 29 sherds from ‘a range of typical coarsewares’ from late pre-Roman Iron Age Silchester, aimed to provide a ‘snapshot of culinary practices’.Footnote 27 The vast majority of extracted residues derived from ruminant adipose fat (i.e. cattle and sheep), with the remainder deriving from a mixture of ruminant and non-ruminant adipose fats (i.e. pigs and chickens). There was no indication of dairy-product processing in any of these vessels.Footnote 28

There has been more limited application of organic residue analysis for the study of Romano-British pots hitherto. Most notable is Cramp et al.'s work on mortaria.Footnote 29 Mortaria first appeared in the Late Iron Age and were traditionally viewed as a distinctively ‘Roman’ form, and therefore an indicator of ‘Romanisation’.Footnote 30 In typical ‘Roman’ cuisine, mortaria are used for grinding spices and making pastes, pestos and sauces,Footnote 31 but it has been suggested that in Roman Britain they were used for more traditional ‘British’ practices, such as dairy-product processingFootnote 32 or cereal processing.Footnote 33 However, the extraction of residues from large numbers of mortarium sherds and comparison with residues from other forms of Roman and Iron Age pots conclusively demonstrated that mortaria were not consistently associated with dairy products. In fact, the use of mortaria reflected a novel type of plant- and animal-resource processing method, but one that broadly fitted in with existing cultural traditions rather than implying a wholesale transition to ‘Romanised’ foodways.Footnote 34 At Faverdale, Co. Durham, and Stanwick, Northamptonshire, where Cramp et al. also analysed a range of domestic wares, mortaria could be clearly distinguished from other cooking wares. They had lower lipid concentrations and a high frequency of plant biomarkers, which were present in very high (greater than 80 per cent) proportions of mortaria. At the rural site of Stanwick, significantly higher proportions of residues were characterised as of dairy origin compared with the major settlement site of Faverdale. This differentiation persisted into the mortaria from each site, indicating that, while mortaria were not specifically a dairy-processing vessel, at Stanwick, dairy products retained their importance from the Iron Age into the Roman period and this pattern could be seen across vessel forms, including more ‘Romanised’ types.Footnote 35

Dairy-product exploitation and processing is a very labour-intensive activity compared to rearing herds of cattle and sheep for slaughter. It is often asserted that dairy production is thought to have died out in Roman Britain, possibly as a result of invasion.Footnote 36 The existing organic residue data discussed above broadly support this hypothesis. However, would individual settlements and regions see a wholesale change from heavy emphasis on dairy products in the Iron Age to very little exploitation in the Roman period, as implied by the data from Silchester and Faverdale? Or did dairy products continue to be exploited on sites which transitioned from the Iron Age to the Roman period, as data suggest at Stanwick? Moreover, did different site types follow different consumption trajectories? As a proto-urban settlement, Silchester was qualitatively different from Copley's sites of Maiden Castle, Danebury Hilfort, Yarnton Cresswell Field and Stanwick. To address these questions, we examine patterns of meat and dairy-product exploitation through the Iron Age to Roman period transition across a broad range of site types in the Cirencester region. Small towns, rural settlements and villas were included, while overtly military and religious sites were excluded.

CIRENCESTER HINTERLAND

The Cirencester Hinterland is defined for this study as the region for which Cirencester can be considered the nearest major Roman city. It is a deliberately vague delineation, as the extent of the Dobunni tribal area is unknown,Footnote 37 as is the subsequent limit of the civitas for which Corinium (Cirencester) was the putative capital.Footnote 38 In the late, pre-Roman Iron Age, the centre of power was probably the oppidum at Bagendon,Footnote 39 which hosted elite, but also ritual, communal and industrial activities. Roman military occupation in the region lasted from around a.d. 50 to the late 70s and forts were established at both Cirencester and Gloucester.Footnote 40 Cirencester was founded around a.d. 60, and it is likely that it eventually replaced Bagendon as a centre of production and exchange,Footnote 41 though it has recently been shown that Cirencester and Bagendon were occupied concurrently in the first century a.d.Footnote 42 Cirencester probably became the capital of the civitas Dobunorum in the early second century a.d. and grew on a scale which outstripped other Romano-British urban centres.Footnote 43 At the end of the third century a.d., under the Diocletianic reforms, Cirencester probably became the capital of Britannia Prima Footnote 44 and in the third and fourth centuries a.d. the number of townhouses in Cirencester continued to grow, in contrast to other Romano-British cities.Footnote 45 Abundant urban occupation at Cirencester continued to the end of easily datable sequences in the early fifth century a.d. and possibly some decades beyond.Footnote 46

The Cirencester Hinterland covers parts of both the Cotswolds and the Upper Thames Valley (FIG. 1). From the middle Iron Age onwards, both areas were reasonably densely settled,Footnote 47 with numbers of settlements increasing in the late Iron Age,Footnote 48 especially in the Upper Thames Valley. Despite the intensity of excavation in the Upper Thames Valley over the last twenty-five yearsFootnote 49 and relative paucity of excavation in the Cotswolds, it appears that there was a genuine difference in settlement patterns between the two regions in the late Iron Age and Roman periods.Footnote 50 In the most recent survey, an almost equal number of villas and farmsteads are recorded in the Cotswolds (40 and 49, respectively), while in the Thames and Avon Vales (grouped) there were 101 farmsteads and only 11 villas.Footnote 51

FIG. 1. Map showing the Cirencester Hinterland with major towns, Roman roads and the study sites indicated. (Roman road data courtesy of McCormick et al. Reference McCormick, Huang, Zambotti and Lavash2013).

The Conquest period is almost invisible in the archaeological record in this region, barring the establishment of major towns at Cirencester and Gloucester.Footnote 52 Even these had little immediate effect on the surrounding area: there was no flurry of newly established villas around first-century a.d. Cirencester as there was at St Albans.Footnote 53 A range of early roadside settlements was established in the Cotswolds in the mid-to-late first century a.d. and followed the layout of the major roads.Footnote 54 However, a major settlement dislocation occurred in the first quarter of the second century a.d. It was widespread in the Upper and Middle Thames Valley, affecting almost all sites across Gloucestershire and Oxfordshire.Footnote 55 New settlements such as WhitewallsFootnote 56 were established, while other settlements such as Thornhill FarmFootnote 57 were abandoned and overlaid with new enclosures and trackways that bore no relation to previous boundaries. Settlements which continued to be occupied often underwent profound change.Footnote 58 For instance, Claydon Pike morphed from a subsistence-level, mixed-agricultural site to one with a specialised focus on haymaking.Footnote 59 This dislocation seems to have happened very quickly, over the course of one generation at most. The Cotswolds seem to have been less severely affected, which some attribute to continuity of landholding by elites who allied with the Roman state, but which may reflect a lack of evidence from non-villa sites.Footnote 60 The reason for the dramatic reorganisation of the Cirencester hinterland is unknown: some suggest either that an external political or economic force must have been involved,Footnote 61 or that the motive may have been to break up any residual Iron Age structures.Footnote 62 It has been noted that early villas were little affected by the settlement change.Footnote 63

Most of the roadside settlements in the Cotswolds and Upper Thames Valley date from the early second century.Footnote 64 Some were quite evenly spaced, such as Dorn, Chesterton and High Cross, all of which are c. 35 km apart on the Fosse Way, or Gloucester, Cirencester and Wanborough at c. 25–30 km along Ermine Street; scholars have been tempted to link the latter with the cursus publicus or at least some kind of official involvement.Footnote 65

The third and fourth centuries saw most established sites continue to be occupied, with the number of villas increasing.Footnote 66 Roadside settlements in both regions were at their most prosperous in the fourth century.Footnote 67 New villas emerged, especially in the Cotswolds, such as Spoonley Wood, and other sites became villas, such as Frocester CourtFootnote 68 and Claydon Pike.Footnote 69 There was some reorganisation of sites and landscapes in this period, but it was much less severe than in the second century and appears to have happened on a much more ad hoc basis, probably related to the creation of Britannia Prima.Footnote 70 At the very end of the Roman period, there is no sign of a dramatic decline in population or settlement occupation, as sometimes hypothesised,Footnote 71 and sites followed a range of trajectories. Some, like Watkins Farm, Whelford Bowmoor and Stubbs Farm, may have been abandoned due to environmental concerns, while others show little evidence for decline.Footnote 72 How long they persisted into the fifth century lies beyond the scope of the study in question.

METHODS

This study analysed pottery from ten sites in the Cirencester Hinterland. Sites were selected primarily on the basis of the ceramic assemblage. Assemblages needed to be substantial enough to provide at least twenty jar sherds from different vessels per period under investigation, to ensure statistical viability. The assemblage also needed to be accessible to the authors for destructive analysis. This meant that most small-scale, trial trench interventions were considered unsuitable. Where possible, sites with high-quality publications were selected, such as Claydon Pike, Cotswold Community and Thornhill Farm. However, the lack of accessible archives or recent publications of Roman villas and small towns in the region meant some smaller investigations were included to ensure full coverage, such as at Chedworth, Asthall and Whitewalls. The study aimed to characterise everyday civilian life, so military and overtly religious sites were excluded.

Ten sites in this region met all the necessary criteria to provide representation of four main site types (major towns, small towns, rural settlements and villas) spanning the period first century b.c.–a.d. fourth century. These four categories inevitably encompass a diverse range of settlements.Footnote 73 The sites sampled were Cirencester and its Iron Age precursor settlement at Kingshill North, ‘small towns’ at Asthall, Whitewalls and Latton Lands,Footnote 74 rural settlements at Claydon Pike, Thornhill Farm and Cotswold Community and two villa sites at KingscoteFootnote 75 and Chedworth. Vessel use across the whole of the Roman period can therefore be examined on an interconnected range of settlements and compared with late Iron Age practices.

As the study aimed to identify everyday dietary habits, it focused where possible on jars, which were the most commonly used cooking vessel in Roman Britain.Footnote 76 Other everyday forms were included in the sample groups where not enough individual jar sherds were present in the assemblage.Footnote 77 There is no reason to assume that the non-diagnostic coarseware cooking wares sampled are biased towards a different or unusual cooking practice that differs from jars. A mixture of black burnished wares and other ubiquitous coarsewares was selected, again to give an overview of everyday cooking and use habits. Rim sherds have been shown in experiments to contain the greatest concentration of lipid,Footnote 78 so these were preferentially selected. Care was taken to avoid adjoining sherds or those which may have originated from the same vessel. Sherds were selected from contexts dated in the published site narratives.Footnote 79

A total of 571 sherds was selected from ten Iron Age and Romano-British sites in the Cirencester Hinterland for lipid extraction and analysis. The assemblage consisted of jars (n = 312) and, where too few jars could be positively identified in the assemblage, other forms (such as bowls) or coarseware fragments not identifiable to form (n = 259) were included. In most cases, such as at Kingshill NorthFootnote 80 and Thornhill Farm,Footnote 81 the majority of unidentified forms are likely to be jars, as these were the overwhelming majority of forms found on site. table 1 summarises the number of sherds sampled on each site by period.

TABLE 1 SHERDS BY PERIOD, SITE AND VESSEL TYPE

The analytical protocol is described in detail elsewhere.Footnote 82 In brief, the surface of a small area of each pottery sherd was removed using a modelling drill to remove any extraneous contamination. This portion was then removed using a solvent-washed chisel and hammer and crushed to a fine powder. Approximately 2 g was weighed into a culture tube and, after the addition of 20 μg n-tetratriacontane as a quantitative internal standard, lipids were simultaneously extracted and transesterified to fatty acid methyl esters using 5 mL of 2 per cent v/v H2SO4 (70 degrees Celsius, 1 h). Aliquots of the lipid extracts were derivatised using BSTFA containing 1 per cent TMCS (BSTFA, 70 degrees Celsius, 1 h) to derivatise any hydroxylated compounds to TMS ethers. Excess BSTFA was removed under N2 and the extract dissolved in hexane. Extracts were screened and quantified using gas chromatography (GC) and characterised using GC/mass spectrometry (GC/MS) and GC-combustion-isotope ratio MS (GC/C/IRMS). Statistical analyses were performed using Graph Pad Prism 9.2.0.

RESULTS

Lipid recovery was generally very good, with assemblages from nearly all sites investigated having significant lipid contents in greater than 75 per cent of sherds. This ranged from 97 per cent of sherds from Kingscote through to 63 per cent of sherds from Asthall, although exceptionally poor preservation was observed at Kingshill North (7 per cent). The generally high overall rates of lipid recovery from investigated sherds are comparable with other cooking wares analysed from Iron Age and Roman Britain.Footnote 83

The absolute lipid concentrations recorded in this study were very high. The mean lipid concentration for the entire assemblage of 571 sherds investigated from 10 sites was 2,154 μg g−1. Within this, the individual site with the highest mean was Kingscote (3,342 μg g-1), echoing the overall lipid recovery rates. Asthall had the lowest mean (524 μg g-1), excluding Kingshill North, which only produced one sherd with a significant lipid content. Box-and-whisker plots describing the lipid concentration data by site are shown in FIG. 2.

FIG. 2. Box-and-whisker plots showing lipid concentration data by site. Colour coding refers to site type: purple = major town; turquoise = small towns; green = rural settlement; blue = villa.

The commodities detected in vessels from all sites were overwhelmingly degraded animal fats, determined by characteristically high proportions of C16:0 and C18:0 fatty acids (see FIG. 3).Footnote 84 This is not indicative that animal products were the sole contributor to diet on these sites: gramme for gramme, meat and milk are significantly fattier than plant products,Footnote 85 and biomarkers of staples such as grain have been shown to persist only in exceptional burial conditions.Footnote 86 However, given the absence of detected plantFootnote 87 or aquaticFootnote 88 biomarkers in the residues, it is likely that the recovered residues derived predominantly from terrestrial animal sources.

FIG. 3. Examples of high-temperature gas chromatograms from all four site types. Triangles with X:Y indicate fatty acids with X number of carbon atoms and Y number of double-bonds; XK indicates ketones with X carbon chain length. Sherd IDs are CIR 35, AS 37, CP 40, CW 01.

Lipid residues can be assigned an origin by comparing the measured δ13C16:0 plotted against the δ13C18:0 fatty acids compared with reference δ13C values derived from modern fats with a known provenance.Footnote 89 Classification is based upon the metabolism of the animals and hence is not species-specific. Residues can be classified as predominantly ruminant adipose fats (meat/carcass fats from ruminant animals such as cattle and sheep); predominantly non-ruminant adipose fats (meat/carcass fats from non-ruminant animals such as pigs and chickens); predominantly dairy fats (milk fats from ruminant animals such as cattle and sheep), or a mixture of the above.Footnote 90 Additions from freshwater and marine fish can also be detected through δ13C values, though mixing with terrestrial fats can mask these signals.Footnote 91 Therefore, additional biomarkers are sought to confirm an aquatic origin. A total of 278 of residues underwent compound-specific stable carbon isotopic analysis to determine the ratios of 13C:12C in the C16:0 and C18:0 fatty acids (δ13C values) in these residues. The majority of residues derived from ruminant adipose sources, but considerable amounts of non-ruminant adipose and milk fats were also identified. The results of these analyses are now discussed by site type. Unless otherwise stated, all percentages expressed below are out of the number of sherds subject to stable carbon isotopic analysis.

CIRENCESTER AND KINGSHILL NORTH

In the first century a.d., the settlement at Cirencester consisted of a fort and a substantial settlement. The forum was targeted for sampling in this period, so the data are likely to reflect civilian rather than military diet. All seven extracted residues from this phase were characterised as degraded animal fats; two residues were characterised as predominantly ruminant dairy fats. The one residue recovered from Kingshill North, the Iron Age precursor settlement, was also characterised as predominantly dairy fat. The remaining five residues from early Cirencester had C16:0 and C18:0 fatty acids with a range of δ13C values that indicated mixing of ruminant and non-ruminant adipose fats. Two sherds from the vicus settlement had δ13C values consistent with a considerable non-ruminant adipose contribution to the residue.Footnote 92 Therefore, pigs and chickens (the main non-ruminant animals present on site) were clearly important additions to the diet in this phase, even in the civilian settlement.

The main street grid and forum basilica were laid out by the early second century and high-quality stone houses were built and occupied. Eleven residues from this period could be characterised: eight derived from a mixture of ruminant and non-ruminant adipose fats, four of which had δ13C values indicative of a considerable contribution of non-ruminant fat to the residues. Fatty acids from one sherd had δ13C values consistent with a purely non-ruminant product origin and, in the absence of aquatic biomarkers, it was judged that this residue probably derived from pig or chicken fat. Exploitation of pigs and chickens in this period seems to increase at the expense of dairy products, which were now absent, and possibly cattle and sheep meat products, though there is still plenty of evidence for exploitation of these species on site.

The third century at Cirencester saw little civic building besides the construction of a masonry town wall which was a common feature of third-century towns in Britain. All 12 residues which could be characterised derived from a mixture of ruminant and non-ruminant adipose fats. Two residues had δ13C values from major fatty acids consistent with a purely non-ruminant source, probably derived from pigs and/or chickens. The remaining ten residues had δ13C values consistent with mixture of ruminant and non-ruminant adipose products. This period sees a very slight decrease in importance of pigs and chickens on site, though they remained an essential contributor to the diet.

The population at Cirencester peaked in the mid-fourth century and a large civic building programme was undertaken in this period.Footnote 93 One residue, out of 13, had δ13C values consistent with a non-ruminant adipose origin, and the remaining 12 had δ13C values indicative of a mixture of ruminant and non-ruminant adipose fats. Pigs and chicken clearly remained very important contributors to diet in the fourth century.

The majority of characterised residues from Cirencester in all periods (shown in FIG. 4) have major fatty acid δ13C values consistent with mixtures of ruminant and non-ruminant adipose products, while no aquatic biomarkers were detected in any residue. The data suggest considerable exploitation of cattle and sheep (ruminants) as well as pigs and chickens (non-ruminants) in all periods at Cirencester, but little to no exploitation of dairy products.

FIG. 4. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from Cirencester and Kingshill North, plotted by century. Ellipses are 1σ confidence ellipses derived from modern reference datasets (Cramp et al. Reference Cramp, Ethier, Urem-Kotsou, Bonsall, Borić, Boroneanţ, Evershed, Perić, Roffet-Salque, Whelton and Ivanova2019, 4, fig. 2) calculated from measured δ13C values from modern UK terrestrial fats from animals raised on a C3 diet (Copley et al. Reference Copley, Berstan, Dudd, Docherty, Mukherjee, Straker, Payne and Evershed2003), adjusted for addition of post-industrial effects of fossil-fuel burning through addition of 1.2‰ (Friedli et al. Reference Friedli, Lötscher, Oeschger, Siegenthaler and Stauffer1986). Solid mixing lines are calculated from the average δ13C ranges of porcine adipose, ruminant adipose, ruminant dairy and freshwater and marine fish (values from Cramp et al. Reference Cramp, Ethier, Urem-Kotsou, Bonsall, Borić, Boroneanţ, Evershed, Perić, Roffet-Salque, Whelton and Ivanova2019). The black dashed line indicates the range below which residues are classified as predominantly dairy fats (Dudd and Evershed Reference Dudd and Evershed1998). The pink dashed line indicates the range above which a residue is classified as >75 per cent non-ruminant origin (Mukherjee et al. Reference Mukherjee, Berstan, Copley, Gibson and Evershed2007), although it should be noted that the non-ruminant threshold is derived solely from porcine reference fats.

SMALL TOWNS

Three small towns were sampled. Asthall was occupied from the first to the fourth centuries a.d.Footnote 94 Whitewalls was occupied from the second/third century to the end of the fourth century a.d.Footnote 95 The Latton Lands site consisted of a late Iron Age settlement which was abandoned in the first century a.d. (see below) and a Roman period roadside settlement, occupied from the second century onwards.Footnote 96 Residues from the Cirencester hinterland small towns are shown in FIG. 5.

FIG. 5. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from the small towns of Asthall, Latton Lands and Whitewalls, plotted by phase. Reference ellipses as fig. 4.

At Roman period Latton Lands, no residues were identified as being of predominantly dairy origin. Similarly at Asthall only two residues, from the first and third centuries, had a predominantly dairy-product origin (12 per cent, n = 2/17) while at Whitewalls, 27 per cent (n = 3/7) of residues from the second/third- and fourth-century sample groups derived from a predominantly dairy origin. The majority of fatty acids from residues from these sites had δ13C values consistent with a purely, or mostly, ruminant adipose fat, indicating a heavy reliance on the meat from ruminant animals (cattle and sheep), with small indications of mixing with non-ruminant products (pigs and chickens) in all periods.

FIG. 5 plots δ13C values from small towns from the second through to the later fourth centuries. They are broadly consistent, showing little diachronic change, until the later fourth century. The pottery from the putative later fourth-century a.d. mansio at Whitewalls produced residues with considerable contributions from non-ruminant products (n = 16), including two residues with δ13C values from major fatty acids consistent with a considerable non-ruminant adipose contribution. No other residues from small towns had such abundant contributions from a non-ruminant adipose source.

RURAL SETTLEMENTS

Four rural settlements were sampled, spanning the late Iron Age and the whole of the Roman period (see FIG. 6). These were the first-century a.d. Iron Age site at Latton Lands;Footnote 97 the late Iron Age settlement at Thornhill Farm, which was abandoned as part of the second-century landscape reforms;Footnote 98 and Claydon Pike and Cotswold Community, settlements originating in the Iron Age which continued to be farmed throughout the Roman period. Cotswold Community broadly avoided the sweeping second-century changes,Footnote 99 while Claydon Pike saw a complete reorganisation of the site, from a mixed agricultural regime to one focused on horticulture and hay production.Footnote 100

FIG. 6. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from the rural settlements of Claydon Pike, Latton lands, Cotswold Community and Thornhill Farm, plotted by century. Inset (shaded grey), the datapoints from second-century Cotswold Community are shown. Reference ellipses as fig. 4.

In the first century b.c., the emphasis at all sites was upon dairy products. At Thornhill Farm, 60 per cent (n = 6/10) of residues could be characterised as predominantly milk fat, while this figure was 67 per cent at Claydon Pike (n = 2/3) and at Cotswold Community (n = 6/9). There was little evidence for non-ruminant contributions to the residues on any site. This trend broadly continued for first-century a.d. residues. At Latton Lands, 100 per cent (n = 5) of residues had a predominantly dairy-product origin, in contrast to none at the second-century Roman small town on the same site, indicating a lack of continuity in site subsistence strategies at this location. At Thornhill Farm, dairy products, attested in 45 per cent (n = 9/20) of residues, remained central to the diet right up until the site's abandonment. At Claydon Pike, dairy products still contributed 67 per cent of the residues (n = 6/9), while one residue had a considerable input of fat of a non-ruminant origin. At Cotswold Community only 9 per cent (n = 1/11) of analysed residues were characterised as predominantly dairy fat.

In the second century, dairy products regained their importance at Cotswold Community, where 62 per cent (n = 8/13) of residues had a predominantly dairy-product origin. At Claydon Pike the residues indicate much greater evidence for mixing of non-ruminant products with ruminant adipose and dairy products, for 79 per cent (n = 11/14) of residues have δ13C values indicative of some additions of non-ruminant adipose fat. This is likely to reflect the dramatic reorganisation of the site in the early second century.

In the third and fourth centuries, residues from both Claydon Pike and Cotswold Community suggest emphasis on meat and milk from ruminant animals and only small amounts of mixing with non-ruminant products. On both sites, 33 per cent (Claydon Pike n = 3/9; Cotswold Community n = 5/15) of residues had a predominantly dairy-product origin, while the remaining residues probably derived from ruminant carcass fats.

VILLAS

Two villa sites were sampled, Kingscote and Chedworth. Kingscote was occupied from the later first century onwardsFootnote 101 and contexts were sampled dating from the second, third and fourth centuries. Although there was probably a villa on the Chedworth site from the second or third century,Footnote 102 only ceramics from the fourth century were accessible. The stable carbon isotope values of major fatty acids from organic residues from pottery from villa sites, including all periods from Kingscote and Chedworth, suggest that the majority of pot residues derived from consistent mixing of ruminant and small amounts of non-ruminant products (FIG. 7), and at Kingscote there was little diachronic change. Only two residues have δ13C values indicative of a considerable contribution of non-ruminant fats, both from second-century Kingscote. There is some evidence for exploitation of dairy products, especially at Chedworth, where 27 per cent (n = 5/18) of residues had a predominantly dairy-product origin. At Kingscote, there was a small contribution from dairy products in all periods.

FIG. 7. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from the two villas of Kingscote and Chedworth, plotted by century. Reference ellipses as fig. 4.

DISCUSSION

It is clear from the data presented above that residues from pots from Cirencester showed much greater contributions of non-ruminant adipose products than any other site in this study. As jars are strongly associated with cooking practices in Roman Britain,Footnote 103 it can be inferred that a much greater quantity of non-ruminant meat was consumed at Cirencester than at any other site type. ‘Non-ruminant animals’ in the context of Roman Britain include all consumed animals that are not cattle, sheep, goats and deer. Therefore, non-ruminants of relevance to this study include pigs and wild boar,Footnote 104 chickens and other domestic or wildfowl,Footnote 105 and fish,Footnote 106, all of which were known to be eaten in Roman Britain, to a greater or lesser extent. However, zooarchaeological evidence from Cirencester paints a much narrower picture. Pigs contributed no more than 20 per cent of any animal bone assemblages at Cirencester. Chickens were much more frequently observed at Cirencester than other sites: four excavated areas within Cirencester provide the four highest counts of chicken on any site in the entire study area.Footnote 107 It is therefore not improbable that chicken fat contributed to the non-ruminant derived residues found here, although degraded porcine and chicken fats cannot be distinguished using organic residue analysis.Footnote 108 Few animal bones at Cirencester have been determined as originating from a wild animal, and of those (including specimens such as crow) very few exhibit butchery marks and few are thought to represent animals that were eaten.Footnote 109 There is little evidence for fish consumption at Cirencester, probably due to a lack of sieving programmes, but as no aquatic biomarkers were detected in the residues (despite performing highly sensitive screening for these biomarkers), we contend that fish was an infrequent contributor to the diet on this site, or were prepared in a way that did not use ceramic cooking pots.

A key finding of this study was the prevalence of milk fats in vessels from rural settlements, both farmsteads and the high-status villa at Chedworth. Milk fats were commonly detected in vessels from the late Iron Age from all sites analysed. This popularity continued through the first century a.d. at Claydon Pike and Thornhill Farm, but at Cotswold Community, reliance on milk products plummeted to less than 10 per cent. It is not clear why this change occurred; the continuity of settlement patterns argues against a population or wholesale cultural change caused by the Roman conquest. In the second century, dairy-product importance increased again, to more than 60 per cent of residues. Notably, the second century saw an increase in the proportion of cattle on site at the expense of sheep, indicating new animal-management strategies.Footnote 110 Therefore the reappearance of dairy products in pottery residues should not be regarded as reflecting reversion to an Iron Age pattern, but rather as forming part of a broader development of new subsistence strategies.

Conversely, at the same time, second-century Claydon Pike saw much greater evidence for mixing of non-ruminant products with ruminant adipose and dairy products: the vast majority of residues have δ13C values indicative of some additions of non-ruminant adipose fat. This rapid change in diet coincided with dramatic material culture change on site in the use patterns of glassware, pottery and dress accessories.Footnote 111 It is possible, then, that the changes in diet were part of the adoption of a ‘wider cultural package’.Footnote 112 Interestingly, the faunal remains from this period show fewer pig remains compared to previous periods, but increased evidence for fishing, fowling and hunting, and domestic fowl was also seen on site.Footnote 113 It is probable, therefore, that the non-ruminant products recorded at Claydon Pike originated from a range of different animals, not merely pigs and chickens. Milk products remained important at both sites, being the predominant component of a third of the residues in the third and fourth centuries, despite zooarchaeological interpretations to the contrary.Footnote 114 Despite its high status, fourth-century Chedworth exhibited a very similar pattern, whereby milk fats were the predominant contributors to 27 per cent of the residues.

In contrast to the rural settlements, dairy products were relatively rarely identified in small towns, with only 13 per cent of analysed residues being characterised as having a predominantly dairy-product origin. Dairy products were identified only in the first century a.d. in one vessel from the vicus settlement at Cirencester and one vessel from the late Iron Age first-century a.d. site at Kingshill North.

The organic residue data clearly show that diet at the major urban centre of Cirencester was different to other site types throughout the Roman period (FIG. 8). However, it does not appear totally alien to the surrounding sites, and instead can be thought of as one end of a spectrum of different dietary practices (FIG. 9). At the other end of this spectrum lie rural sites, which show very little evidence for consumption of non-ruminant animal products on a regular basis, instead relying heavily on ruminant products, both meat and milk. Villas and small towns fall roughly between, with pot residues revealing less emphasis on dairy products than is observed at rural sites, but showing significantly less evidence for non-ruminant products too. Meanwhile, dairying continued to be practised at rural sites down to the end of the Roman period, including on the villa site at Chedworth.

FIG. 8. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from all sites, plotted by century. Reference ellipses as fig. 4.

FIG. 9. (opposite). Statistical analysis comparing Δ13C values of residues from all sites by century. Error bars represent 1σ confidence. Δ13C is calculated by δ13C18:0 – δ13C 16:0. Δ13C therefore provides a measure of difference between the δ13C values, allowing direct comparison between different sites (Copley et al. Reference Copley, Berstan, Dudd, Docherty, Mukherjee, Straker, Payne and Evershed2003). The first-century a.d. plot compares Δ13C (‰) of major fatty acids from sherds from Cirencester and rural sites (two-tailed t-test, * = P < 0.05). The second-century a.d. plot compares Δ13C (‰) of fatty acids from Cirencester, Small Towns, Villas and rural sites (One-way ANOVA with Tukey adjustment for multiple comparisons, * = P < 0.05, ** = P < 0.01, **** = P < 0.0001). The third-century plot compares Δ13C (‰) of fatty acids from Cirencester, Small Towns, Villas and rural sites (One-way ANOVA with Tukey adjustment for multiple comparisons, * = P < 0.05). The fourth-century plot compares Δ13C (‰) of fatty acids from Cirencester, Small Towns, Villas and rural sites (One-way ANOVA with Tukey adjustment for multiple comparisons, * = P < 0.05, ** = P < 0.01, *** = P < 0.001).

Undoubtedly, some of this difference will have been driven by cultural factors, such as consumer desire in cities and possible rejection of new foods at rural sites. It is also extremely likely that the foods reflected in the residues will have been subject to different cooking practices, different methods of preparation, and accompanied by different ingredients on different sites; many of these developments will have been driven by cultural ideas about taste and economic factors such as access to a wider market economy. However, we contend that the main driver towards the differences seen between Cirencester and its hinterland was the increasing need to extensify food production: that is, to produce more food for the same labour input,Footnote 115 through the introduction of new animal subsistence strategies on urban and rural sites.

NEW ANIMAL SUBSISTENCE STRATEGIES

TOWNS

Across Britain, cattle and sheep are usually thought to have been raised outside urban settlements, often in the site's hinterland, and brought to the city for slaughter and consumption or market redistribution. The butchery practices used in cities and by the Roman army are clearly distinguishable from those used elsewhere,Footnote 116 and it has been suggested that the brutality of these practices implies that animals were being processed by people other than those who raised them.Footnote 117 Strontium isotope ratios, which provide direct evidence for the non-local origin of individual animals, show that cattle recovered from Owslebury, Hampshire, could have come from the local area in the middle Iron Age, but that by the late Iron Age and early Roman periods the site was part of a wider exchange network or market.Footnote 118 In the Roman period some cattle came to the site from at least 70 km away. Similarly, at Caerleon, Wales, strontium isotope ratios indicate that while the majority of animals could have come from the local area, others must have originated further afield.Footnote 119

Pigs rarely make a large contribution to faunal assemblages from rural sites in the Cirencester hinterland, especially in the Upper Thames Valley. There was a slight increase in percentage quantities of pigs on later Roman sites than earlier but the overall contribution remained small.Footnote 120 Chickens are thought rarely to have been raised on rural settlements; they contributed only 1.8 per cent of the combined sheep- and chicken-bone counts on these sites.Footnote 121 There was relatively little woodland cover in the Cirencester hinterland at this time, around 10–15 per cent,Footnote 122 which is thought to have been mostly hedges and similar plantations. This is not particularly suited to traditional pannage-type husbandry. It is harder to suggest an environmental cause for the lack of chickens on rural sites, as chickens tend to thrive in farmstead-like settings.Footnote 123 It is possible that this was a deliberate rejection on the part of rural Romano-Britons, who perhaps viewed the recently introduced birds as unusual or exotic animals, associated with ritual and funerary events, rather than a mundane food source.Footnote 124 Another possibility for low uptake could have been a lack of knowledge about how to husband poultry successfully:Footnote 125 the majority of people probably only encountered them on infrequent trips to major cities, or during ritual activities.

We consider the emphasis on pig and chicken products at Cirencester to be an example of urban extensification. At this location, both pig and chicken bones had relatively enriched δ13C and δ15N isotope values compared with cattle and sheep.Footnote 126 This is consistent with these animals being fed a mixture of animal and vegetable protein, possibly indicating a ‘kitchen scraps’-type diet. Significant numbers of neonatal pig bones have been found on a range of urban sites such as Silchester,Footnote 127 and pig slurry has been identified at Leicester.Footnote 128 Pigs and chickens can therefore be considered ‘recycling’ animals: they convert human-inedible foodstuffs to human-edible foodstuffs (i.e. themselves), grow relatively quickly and can be raised in a relatively small space. It is likely that, where possible, people living in major towns produced their own meat supply by raising pigs and chickens on site. This was heavily supplemented by cattle and sheep brought in from the settlement hinterland. Towns were therefore by no means self-sustaining, but resourceful townspeople produced their own food where possible. We propose that this is the first evidence of urban extensification of food production in Roman Britain.

RURAL SETTLEMENTS

Milk products are generally thought rarely to have been exploited in Roman Britain,Footnote 129 in stark contrast to the Iron Age. This view is usually extrapolated from a lack of neonatal cattle bones, which would indicate infant slaughter often associated with dairying practices,Footnote 130 and by the increasing trend towards male cattle in Romano-British herds. It has often been argued that the emphasis on larger, male cattle in the Roman period was the result of their being used predominantly for traction.Footnote 131 Writing specifically on the Cirencester hinterland, Hesse declared that the zooarchaeology provides no evidence for significant dairying practices.Footnote 132 However, milk fats were found to be predominant in 46 per cent of residues from Roman period vessels from Claydon Pike and Cotswold Community, two of the same sites as Hesse's zooarchaeological evidence. Zooarchaeological evidence from both sites gives little indication that either cattle or sheep were exploited solely for milk, even in the Iron Age.Footnote 133 Indeed, there is no reason both species could not have been exploited in parallel, as ethnographic data show was common in twentieth-century rural Greece.Footnote 134 How, then, can the increasing emphasis on male cattle be explained?

The continued exploitation of dairy products on rural settlements should not be seen as the unproblematic continuation of Iron Age practices. The shift from milk to meat to milk seen in first-century b.c.–a.d. second-century Cotswold Community strongly indicates that the trend is more complex than a simple tradition handed down between generations. Moreover, exploitation of dairy products cannot be taken as the rejection of ‘Roman’ foodways in favour of ‘British’ foodways (whatever these might be), as dairy products were heavily utilised at the high-status villa at Chedworth and at Claydon Pike, where many high-status ‘Roman’ small finds and structures were recorded. Instead, we see the exploitation of dairy products as another example of extensification in the face of the new pressures caused by integration into the Roman economy.

It has been hypothesised that cattle in the Iron Age may have had a very similar status to those in modern agro-pastoral societies, where livestock are central to many forms of social exchange.Footnote 135 Early Medieval Ireland provides such a parallel. Most small settlements could not consume a whole bovine carcass before it began to spoil, so killing a cow became an event with significance, often at community gatherings.Footnote 136 Dairy herding, on the other hand, could produce milk and milk derivatives such as cheese and butter at household-level efficiency. From the second century onwards, however, having enough people at a settlement to consume the animal was no longer a problem, due to the new existence of centralised markets with professional butchers to buy the cattle.Footnote 137 Moreover, dairying is very labour intensive compared to meat farming, and so a less practical way of producing the surplus required to feed the growing population of Britain. Therefore, we suggest that rural sites trended away from dairying practices as their main focus and, as a result, dairy products were rarely exported to towns. However, dairying continued to be practised on an ad hoc basis, probably around weaning time, as a way of supplying extra food to the inhabitants of the rural settlements themselves. In this way, rural inhabitants of the Cirencester hinterland extensified their animal husbandry practices.

CONCLUSION

The study aimed, through characterising the origins of organic residues surviving in the fabric of everyday cooking pots, to investigate the changing consumption and subsistence practices within the Cirencester hinterland, taking account of a range of site types, from major towns to small towns, rural farmsteads and villas and examining a broad chronological span from the late Iron Age to the end of the Roman period.

It demonstrates that although diet at Cirencester was different from other sites, it was on one end of a spectrum of possible diets, with rural settlements representing the other end. However, this was not a simple producer–consumer relationship: instead, Cirencester's occupants consumed both ruminant animals (cattle and sheep) raised in the surrounding settlements and non-ruminant animals (pigs and chickens) probably raised within the city itself. Dairy products were never widely consumed at Cirencester and only rarely contributed to diet in small towns.

However, at rural sites, including the villa at Chedworth, dairy products remained important through the end of the fourth century. Dairying was practised less frequently in the later centuries at rural sites, however, which we have interpreted as a move away from a mainly dairying economy in the late Iron Age to one in which dairying was undertaken as it suited the broader agricultural cycle.

The economic pressure to feed the non-food-producing population and produce a surplus for taxation led to extensification (producing more food by cultivating more land with less labour input) of both arable and pastoral farming. In Cirencester itself, people used pigs and chickens as a way of ‘recycling’ their food scraps and supplementing their diet. On rural sites, people trended away from the labour-intensive practice of dairying, focusing instead on mostly meat production, probably while using cattle for traction to plough heavier soils for arable farming. Dairy products remained important contributors to the rural diet, however, probably on a seasonal basis.Footnote 138

This study has been the first regional exploration of Roman Britain using organic residue analysis. It has been able to highlight relationships between different site types not visible from other evidence. The success of this approach in elucidating evidence of the past otherwise invisible from other remains demonstrates the value of this technique to the wider study of Roman Britain, as well as economies of other periods and geographies.

ACKNOWLEDGEMENTS

The authors would like to thank the Arts and Humanities Research Council for funding this research through the South West and Wales Doctoral Training Partnership. Compound-specific stable isotope analyses were performed through two grants-in-kind from the NERC Life Sciences and Mass Spectrometry Facility (now NEIF): LSMSF-BRIS/95/1016 and LSMSF-B BRIS/112/0118. Sherds for analysis were provided by Corinium Museum, Wiltshire Museum, the Oxfordshire Museums Service, Swindon Museums and Galleries and the National Trust.

Finally, the authors would like to thank Britannia's anonymous reviewers for their constructive comments; Peter Guest for invaluable assistance with the first draft; Terence Christian for producing fig 1; Luke Dabin for assistance with statistics, and Martin Pitts and Richard Evershed for their comments on the PhD thesis from which this paper originated.

SUPPLEMENTARY MATERIAL

For supplementary material for this article, please visit https://doi.org/10.1017/S0068113X23000181.

Footnotes

1 Perring and Pitts Reference Perring and Pitts2013.

2 Livarda and Orengo Reference Livarda and Orengo2015.

3 e.g. Hingley Reference Hingley and Miles1982; Millett Reference Millett1990.

4 Van der Veen Reference Van der Veen and Twiss2007.

5 Corbier Reference Corbier, Rich and Wallace-Hadrill1991; Stallibrass Reference Stallibrass, Driessen, Heeren, Hendriks, Kemmers and Visser2009.

6 Fulford and Allen Reference Fulford, Allen and Bird2017.

7 Fulford and Allen Reference Fulford, Allen and Bird2017, 8.

8 Lodwick Reference Lodwick, Allen, Lodwick, Brindle, Fulford and Smith2017, 36–7.

9 Brindle Reference Brindle, Allen, Lodwick, Brindle, Fulford and Smith2017, 42.

10 Maltby Reference Maltby, Croxford, Ray and Roth2007.

11 Allen and Lodwick Reference Allen, Lodwick, Allen, Lodwick, Brindle, Fulford and Smith2017, 145.

12 Evershed Reference Evershed2008a.

13 Miller et al. Reference Miller, Whelton, Swift, Maline, Hammann, Cramp and McCleary2020.

14 Dudd and Evershed Reference Dudd and Evershed1998; Copley et al. Reference Copley, Berstan, Dudd, Straker, Payne and Evershed2005.

15 Craig et al. Reference Craig, Forster, Andersen, Koch, Crombé, Milner, Stern, Bailey and Heron2007.

16 Evershed et al. Reference Evershed, Vaughan, Dudd and Soles1997; Kimpe et al. Reference Kimpe, Jacobs and Waelkens2002.

17 Evershed et al. Reference Evershed, Payne, Sherratt, Copley, Coolidge, Urem-Kotsu, Kotsakis, Özdoğan, Özdoğan, Nieuwenhuyse, Akkermans, Bailey, Andeescu, Campbell, Farid, Hodder, Yalman, Özbaşaran, Bıçakcı, Garfinkel, Levy and Burton2008a.

18 Cramp et al. Reference Cramp, Evershed, Lavento, Halinen, Mannermaa, Oinonen, Kettunen, Perola, Onkamo and Heyd2014b.

19 Dunne et al. Reference Dunne, Evershed, Salque, Cramp, Bruni, Ryan, Biagetti and di Lernia2012.

20 For an overview of detectable commodities, see Roffet-Salque et al. Reference Roffet-Salque, Dunne, Altoft, Casanova, Cramp, Smyth, Whelton and Evershed2017.

21 Dudd and Evershed Reference Dudd and Evershed1998.

22 Craig et al. Reference Craig, Forster, Andersen, Koch, Crombé, Milner, Stern, Bailey and Heron2007; Reference Craig, Steele, Fischer, Hartz, Andersen, Donohoe, Glykou, Saul, Jones, Koch and Heron2011; Cramp and Evershed Reference Cramp, Evershed, Holland and Turekian2014.

23 Evershed et al. Reference Evershed, Heron and Goad1991; Charters et al. Reference Charters, Evershed, Blinkhorn and Denham1995; Regert et al. Reference Regert, Vacher, Moulherat and Decavallas2003.

24 Cramp and Evershed Reference Cramp, Evershed, Spataro and Villing2015, 130.

25 Whelton et al. Reference Whelton, Hamman, Cramp, Dunne, Roffet-Salque and Evershed2021.

26 Copley et al. Reference Copley, Berstan, Dudd, Straker, Payne and Evershed2005.

27 Colonese et al. Reference Colonese, Lucquin, Timby, Craig, Fulford, Clarke, Durham and Pankhurst2018.

28 Colonese et al. Reference Colonese, Lucquin, Timby, Craig, Fulford, Clarke, Durham and Pankhurst2018, 226.

29 Cramp et al. Reference Cramp, Evershed and Eckardt2011; Reference Cramp, Evershed, Eckardt and Schrüfer-Kolb2012.

30 e.g. Tyers Reference Tyers1996, 116; Alcock Reference Alcock2001.

31 Cramp et al. Reference Cramp, Evershed and Eckardt2011.

32 Alcock Reference Alcock2001; Cool Reference Cool2006.

33 Oswald Reference Oswald1944.

34 Cramp et al. Reference Cramp, Evershed and Eckardt2011.

35 Cramp et al. Reference Cramp, Evershed, Eckardt and Schrüfer-Kolb2012, 103–4.

36 e.g. Hesse Reference Hesse2011, on the basis of zooarchaeology.

37 McWhirr Reference McWhirr1981.

38 Holbrook Reference Holbrook2008.

39 Moore Reference Moore, Holbrook and Juřica2006, 76.

40 McWhirr Reference McWhirr1981, 11.

41 Holbrook Reference Holbrook2008, 301; Moore Reference Moore and Breeze2014, 29.

42 Moore Reference Moore and Moore2020, 582–6.

43 Smith Reference Smith, Miles, Palmer, Smith and Jones2007a, 379.

44 White Reference White2007; Smith Reference Smith, Miles, Palmer, Smith and Jones2007b, 392.

45 Faulkner Reference Faulkner and Holbrook1998, 379–83.

46 Smith (Reference Smith, Miles, Palmer, Smith and Jones2007b, 401) cautions against assuming that Cirencester ceased to function as a settlement or central place at the end of the fourth century, while White Reference White2007 suggests that Britannia Prima survived in some form until the Anglo-Saxon conquest of the region in the sixth century, albeit in a changed form.

47 Moore Reference Moore, Holbrook and Juřica2006; Hey Reference Hey, Haselgrove and Moore2007.

48 Smith Reference Smith, Miles, Palmer, Smith and Jones2007a.

49 Allen and Lodwick Reference Allen, Lodwick, Allen, Lodwick, Brindle, Fulford and Smith2017.

50 Smith Reference Smith, Miles, Palmer, Smith and Jones2007a.

51 Smith Reference Smith, Smith, Allen, Brindle and Fulford2016, 146, table 5.2.

52 Henig and Booth Reference Henig and Booth2000, 51; Holbrook Reference Holbrook, Holbrook and Juřica2006, 102; Smith Reference Smith, Miles, Palmer, Smith and Jones2007a.

53 Holbrook Reference Holbrook2008, 318.

54 Timby Reference Timby1998; Smith Reference Smith, Smith, Allen, Brindle and Fulford2016, 165.

55 Henig and Booth Reference Henig and Booth2000, 51; Holbrook Reference Holbrook, Holbrook and Juřica2006, 102; Smith Reference Smith, Miles, Palmer, Smith and Jones2007a, 377.

56 Also called Easton Grey: Wilmott and Shipp Reference Wilmott and Shipp2006.

57 Jennings et al. Reference Jennings, Muir, Palmer and Smith2004.

58 Holbrook Reference Holbrook2008, 319.

59 Miles et al. Reference Miles, Palmer, Smith and Jones2007.

60 Smith Reference Smith, Miles, Palmer, Smith and Jones2007a, 378; Holbrook Reference Holbrook2008, 319.

61 Holbrook Reference Holbrook2008, 318.

62 Hingley Reference Hingley1989, 105.

63 Henig and Booth Reference Henig and Booth2000, 110.

64 Smith Reference Smith, Smith, Allen, Brindle and Fulford2016, 166.

65 Timby Reference Timby1998, 430–1; Smith Reference Smith, Miles, Palmer, Smith and Jones2007a, 390.

66 Henig and Booth Reference Henig and Booth2000, 106; Holbrook Reference Holbrook, Holbrook and Juřica2006, 108; Smith Reference Smith, Smith, Allen, Brindle and Fulford2016, 160.

67 Timby, Reference Timby1998, 139; Smith Reference Smith, Miles, Palmer, Smith and Jones2007b, 393.

68 Price Reference Price2000.

69 Miles et al. Reference Miles, Palmer, Smith and Jones2007.

70 Smith Reference Smith, Miles, Palmer, Smith and Jones2007b, 395; 2016, 148.

71 Faulkner Reference Faulkner2000, 253–4.

72 Smith Reference Smith, Miles, Palmer, Smith and Jones2007b, 396.

73 e.g. Allen and Smith Reference Allen, Smith, Smith, Allen, Brindle and Fulford2016 discuss the wide range of forms generally described as ‘rural settlements’.

74 ‘Small town’ is a catch-all category encompassing roadside settlements as well as more obviously ‘urban’ sites (Timby Reference Timby1998, 3–5). All three ‘small town’ sites in this study lie on major Roman roads and were newly established at the beginning of the Roman period, distinguishing them from the ‘rural settlement’ category.

75 ‘Villa’ is a somewhat contested term. Timby (Reference Timby1998, 290–3) describes Kingscote as a ‘Roman estate centre’ specialising in large-scale arable agriculture, including milling and malting of grain ‘over and beyond the usual domestic requirements’, and on this basis we include it as a ‘villa’, though it lacks the typical features of mosaics or hypocausts.

76 Cool (Reference Cool2006, 39) reports that they are the most frequently sooted vessel form across the province.

77 A detailed description of sherds, their contextual information and associated organic residues can be found in the supplementary information.

78 Charters et al. Reference Charters, Evershed, Goad, Leyden, Blinkhorn and Denham1993; Historic England 2017, 19.

79 See supplementary information for details on context of each sherd selected.

80 Biddulph Reference Biddulph, Biddulph and Welsh2011.

81 Timby Reference Timby, Jennings, Muir, Palmer and Smith2004.

82 Correa-Ascencio and Evershed Reference Correa-Ascencio and Evershed2014.

83 Colonese et al. Reference Colonese, Lucquin, Timby, Craig, Fulford, Clarke, Durham and Pankhurst2018; Cramp et al. Reference Cramp, Evershed and Eckardt2011; Reference Cramp, Evershed, Eckardt and Schrüfer-Kolb2012.

84 Pothoven et al. Reference Pothoven, Beitz and Zimmerli1974; Deeth and Christie Reference Deeth and Christie1979.

85 Evershed Reference Evershed2008b, 34.

86 Hammann and Cramp Reference Hammann and Cramp2018.

87 Such as wax esters and their degradation products: Evershed et al. Reference Evershed, Heron and Goad1991; Cramp et al. Reference Cramp, Evershed and Eckardt2011; Dunne et al. Reference Dunne, Mercuri, Evershed, Bruni and di Lernia2016.

88 Such as long-chain ω-(o-alkylphenyl)alkanoic acids (APAAs) and isoprenoid fatty acids: Evershed et al. Reference Evershed, Copley, Dickson and Hansel2008b; Cramp et al. Reference Cramp, Jones, Sheridan, Smyth, Whelton, Mulville, Sharples and Evershed2014a.

89 Reference fats used in this study are listed in the supplementary information.

90 Copley et al. Reference Copley, Berstan, Dudd, Docherty, Mukherjee, Straker, Payne and Evershed2003, 1526; Evershed et al. Reference Evershed, Copley, Dickson and Hansel2008b.

91 Cramp and Evershed Reference Cramp, Evershed, Spataro and Villing2015.

92 Non-ruminant contributions determined after Mukherjee et al. Reference Mukherjee, Berstan, Copley, Gibson and Evershed2007.

93 Faulkner Reference Faulkner and Holbrook1998, 378–9, fig. 206.

94 Booth Reference Booth1997.

95 Wilmott and Shipp Reference Wilmott and Shipp2006.

96 Powell et al. Reference Powell, Laws and Brown2009.

97 Powell et al. Reference Powell, Laws and Brown2009.

98 Jennings et al. Reference Jennings, Muir, Palmer and Smith2004.

99 Powell et al. Reference Powell, Smith, Laws, Allen and Wachnik2010.

100 Miles et al. Reference Miles, Palmer, Smith and Jones2007.

101 Timby Reference Timby1998, 287.

102 Esmonde-Cleary Reference Esmonde Cleary2013, 19.

103 Cool Reference Cool2006; Marshall and Seeley Reference Marshall and Seeley2018.

104 Cool Reference Cool2006, though Maltby Reference Maltby, Millett, Revell and Moore2016 cautions that it may be mistaken for large domesticated pig in zooarchaeological records.

105 Yalden and Albarella Reference Yalden and Albarella2008.

106 Locker Reference Locker2007.

107 Maltby Reference Maltby and Bird2017, fig. 7.

108 Colonese et al. Reference Colonese, Lucquin, Guedes, Thomas, Best, Fothergill, Sykes, Foster, Miller, Poole, Maltby, Von Tersch and Craig2017 proposed a novel methodology for doing so, by creating site-specific standards based on animal bone assemblages. This was outside the scope of this study.

109 Maltby Reference Maltby and Holbrook1998.

110 Strid Reference Strid, Powell, Smith and Laws2010, 217.

111 Cool Reference Cool2006, 134.

112 Cool Reference Cool2006, 134.

113 Sykes Reference Sykes, Miles, Palmer, Smith and Jones2007, 151.

114 e.g. Hesse Reference Hesse2011.

115 Allen and Lodwick Reference Allen, Lodwick, Allen, Lodwick, Brindle, Fulford and Smith2017.

116 Maltby Reference Maltby, Croxford, Ray and Roth2007.

117 Allen Reference Allen, Smith, Allen, Brindle, Fulford, Lodwick and Rohnbogner2018.

118 Minniti et al. Reference Minniti, Valenzuela-Lamas, Evans and Albarella2014.

119 Madgwick et al. Reference Madgwick, Lewis, Grimes and Guest2019.

120 Booth et al. Reference Booth, Dodd, Robinson and Smith2007, 295.

121 Maltby et al. Reference Maltby, Allen, Best, Fothergill and Demarchi2018.

122 Rippon et al. Reference Rippon, Smart and Pears2015.

123 Sykes Reference Sykes2012.

124 Chickens were introduced to Britain in the late Iron Age: Cool Reference Cool2006; Sykes Reference Sykes2012; Maltby et al. Reference Maltby, Allen, Best, Fothergill and Demarchi2018.

125 Yalden and Albarella Reference Yalden and Albarella2008 report little evidence for poultry keeping in the Iron Age.

126 Cummings Reference Cummings, Driessen, Heeren, Hendriks, Kemmers and Visser2009.

127 Ingrem Reference Ingrem and Fulford2012.

128 Maltby Reference Maltby, Fulford and Holbrook2015, 184.

129 e.g. Hesse Reference Hesse2011; Allen Reference Allen, Smith, Allen, Brindle, Fulford, Lodwick and Rohnbogner2018 problematises this view.

130 See McCormick Reference McCormick1992 for a problematisation of this pattern.

131 Hesse Reference Hesse2011.

132 Hesse Reference Hesse2011, 241.

133 Sykes Reference Sykes, Miles, Palmer, Smith and Jones2007, 54–5; Strid Reference Strid, Powell, Smith and Laws2010, 211.

134 Halstead Reference Halstead, Rowley-Conwy, Sergeantson and Halstead2017.

135 Allen Reference Allen, Smith, Allen, Brindle, Fulford, Lodwick and Rohnbogner2018, 88.

136 McCormick Reference McCormick, Miracle and Milner2002.

137 Maltby Reference Maltby, Fulford and Holbrook2015.

138 Hesse Reference Hesse2011; Allen Reference Allen, Allen, Lodwick, Brindle, Fulford and Smith2017; Reference Allen, Smith, Allen, Brindle, Fulford, Lodwick and Rohnbogner2018.

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Figure 0

FIG. 1. Map showing the Cirencester Hinterland with major towns, Roman roads and the study sites indicated. (Roman road data courtesy of McCormick et al.2013).

Figure 1

TABLE 1 SHERDS BY PERIOD, SITE AND VESSEL TYPE

Figure 2

FIG. 2. Box-and-whisker plots showing lipid concentration data by site. Colour coding refers to site type: purple = major town; turquoise = small towns; green = rural settlement; blue = villa.

Figure 3

FIG. 3. Examples of high-temperature gas chromatograms from all four site types. Triangles with X:Y indicate fatty acids with X number of carbon atoms and Y number of double-bonds; XK indicates ketones with X carbon chain length. Sherd IDs are CIR 35, AS 37, CP 40, CW 01.

Figure 4

FIG. 4. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from Cirencester and Kingshill North, plotted by century. Ellipses are 1σ confidence ellipses derived from modern reference datasets (Cramp et al.2019, 4, fig. 2) calculated from measured δ13C values from modern UK terrestrial fats from animals raised on a C3 diet (Copley et al.2003), adjusted for addition of post-industrial effects of fossil-fuel burning through addition of 1.2‰ (Friedli et al.1986). Solid mixing lines are calculated from the average δ13C ranges of porcine adipose, ruminant adipose, ruminant dairy and freshwater and marine fish (values from Cramp et al.2019). The black dashed line indicates the range below which residues are classified as predominantly dairy fats (Dudd and Evershed 1998). The pink dashed line indicates the range above which a residue is classified as >75 per cent non-ruminant origin (Mukherjee et al.2007), although it should be noted that the non-ruminant threshold is derived solely from porcine reference fats.

Figure 5

FIG. 5. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from the small towns of Asthall, Latton Lands and Whitewalls, plotted by phase. Reference ellipses as fig. 4.

Figure 6

FIG. 6. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from the rural settlements of Claydon Pike, Latton lands, Cotswold Community and Thornhill Farm, plotted by century. Inset (shaded grey), the datapoints from second-century Cotswold Community are shown. Reference ellipses as fig. 4.

Figure 7

FIG. 7. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from the two villas of Kingscote and Chedworth, plotted by century. Reference ellipses as fig. 4.

Figure 8

FIG. 8. Scatter plot showing δ13C16:0 values plotted against δ13C18:0 for sherds from all sites, plotted by century. Reference ellipses as fig. 4.

Figure 9

FIG. 9. (opposite). Statistical analysis comparing Δ13C values of residues from all sites by century. Error bars represent 1σ confidence. Δ13C is calculated by δ13C18:0 – δ13C 16:0. Δ13C therefore provides a measure of difference between the δ13C values, allowing direct comparison between different sites (Copley et al.2003). The first-century a.d. plot compares Δ13C (‰) of major fatty acids from sherds from Cirencester and rural sites (two-tailed t-test, * = P < 0.05). The second-century a.d. plot compares Δ13C (‰) of fatty acids from Cirencester, Small Towns, Villas and rural sites (One-way ANOVA with Tukey adjustment for multiple comparisons, * = P < 0.05, ** = P < 0.01, **** = P < 0.0001). The third-century plot compares Δ13C (‰) of fatty acids from Cirencester, Small Towns, Villas and rural sites (One-way ANOVA with Tukey adjustment for multiple comparisons, * = P < 0.05). The fourth-century plot compares Δ13C (‰) of fatty acids from Cirencester, Small Towns, Villas and rural sites (One-way ANOVA with Tukey adjustment for multiple comparisons, * = P < 0.05, ** = P < 0.01, *** = P < 0.001).

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