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MINIMALLY DESTRUCTIVE RADIOCARBON DATING OF CAPRINE DUNG

Published online by Cambridge University Press:  05 September 2023

Daniel Fuks*
Affiliation:
McDonald Institute for Archaeological Research, Dept. of Archaeology, University of Cambridge, Cambridge, UK
Niamh O’Neill-Munro
Affiliation:
14CHRONO Centre for Climate, the Environment and Chronology, Queen’s University Belfast, Belfast, UK
Paula J Reimer
Affiliation:
14CHRONO Centre for Climate, the Environment and Chronology, Queen’s University Belfast, Belfast, UK
Tali Erickson-Gini
Affiliation:
Israel Antiquities Authority, Omer, Israel
Guy Bar-Oz
Affiliation:
School of Archaeology and Maritime Cultures, University of Haifa, Haifa, Israel
Roy Galili
Affiliation:
Department of Bible, Archaeology and Ancient Near Eastern Studies, Ben-Gurion University of the Negev, Beer Sheva, Israel
Scott Bucking
Affiliation:
Department of History, DePaul University, Chicago, Illinois, USA
*
*Corresponding author. Email: [email protected]
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Abstract

Archaeological dung pellets are time capsules of ancient herbivore diets and gut flora, informing on past agropastoral activity, ecology, and animal health. Improving multi-proxy approaches is key to maximizing this finite archaeological resource. Through experiments with standard pretreatments used in radiocarbon (14C) dating, we address a fundamental problem in maximal multi-proxy analysis: How to chronometrically date individual caprine pellets while conserving as much as possible for additional analyses? We applied acid-alkali-acid (AAA) or acid-only pretreatments to 37 samples of ancient and recent sheep/goat dung pellets from sites in the Negev desert, Israel, measuring weight-loss due to pretreatment. Shavings of outer surfaces and remaining inner pellets of four pairs were dated and compared. We found that (i) sample-specific factors affect pretreatment survivability, including preservation quality and initial sample size; (ii) given sufficient start weight, AAA can be used to pretreat sheep/goat coprolites; (iii) 100 mg appeared a desirable minimum sample weight before pretreatment; and (iv) shavings of coprolites’ outer surface produced 14C dates equivalent to dates obtained from inner coprolites. Whereas standard coprolite analysis protocols discard shavings removed from outer surfaces to avoid contamination, our findings indicate their efficacy for 14C dating. This offers an important addition to workflows for multi-proxy coprolite analysis.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of University of Arizona

INTRODUCTION

Coprolites, or ancient feces, are increasingly under investigation by researchers interested in records of past economy, environment, and evolution (Hunt et al. Reference Hunt, Milàn, Lucas and Spielmann2012; Qvarnström et al. Reference Qvarnström, Niedźwiedzki and Žigaitė2016; Shillito et al. Reference Shillito, Blong, Green and van Asperen2020). A variety of techniques are employed in coprolite analysis (e.g., Miller Reference Miller1984; Poinar et al. Reference Poinar, Hofreiter, Spaulding, Martin, Stankiewicz, Bland, Evershed, Possnert and Pääbo1998; Kühn et al. Reference Kühn, Maier, Herbig, Ismail-Meyer, Le Bailly and Wick2013; Linseele Reference Linseele, Riemer, Baeten, De Vos, Marinova and Ottoni2013; Camacho et al. Reference Camacho, Araújo, Morrow, Buikstra and Reinhard2018; Égüez and Makarewicz Reference Égüez and Makarewicz2018; Sistiaga et al. Reference Sistiaga, Mallol, Galván and Summons2014; Perrotti and van Asperen Reference Perrotti and van Asperen2019; Zhang et al. Reference Zhang, van Geel, Gosling, McMichael, Jansen, Absalah, Sun and Wu2019; Wood et al. Reference Wood, Richardson, McGlone and Wilmshurst2020), and many studies apply multiple techniques to different coprolites in an assemblage (Reinhard and Bryant Reference Reinhard and Bryant1992; di Lernia Reference di Lernia2001; Delhon et al. Reference Delhon, Martin, Argant and Thiébault2008; Shahack-Gross Reference Shahack-Gross2011; Marinova et al. Reference Marinova, Ryan, Van Neer and Friedman2013; Pineda et al. Reference Pineda, Saladié, Expósito, Rodríguez-Hidalgo, Cáceres, Huguet, Rosas, López-Polín, Estalrrich, García-Tabernero and Vallverdú2017; Baeten et al. Reference Baeten, Mees, Marinova, de Dapper, de Vos, Huyge, van Strydonck, Vandenberghe and Linseele2018; Landau et al. Reference Landau, Dvash, Ryan, Saltz, Deutch and Rosen2020). Yet the full benefits of the multi-proxy approach will be realized when different complementary analyses are applied to each individual coprolite investigated, making the most of this finite archaeological resource (Fuks and Dunseth Reference Fuks and Dunseth2021). Meanwhile, multi-proxy approaches to analyzing individual coprolites are being employed and refined (Dunseth et al. Reference Dunseth, Fuks, Langgut, Weiss, Butler, Yan, Boaretto, Tepper, Bar-Oz and Shahack-Gross2019; Jouy-Avantin et al. Reference Jouy-Avantin, Debenath, Moigne and Moné2003; Rifkin et al. Reference Rifkin, Vikram and Ramond2020; Romaniuk et al. Reference Romaniuk, Panciroli and Buckley2020; Polling et al. Reference Polling, ter Schure and van Geel2021; Velázquez et al. Reference Velázquez, Tosto, Benvenuto, Fernández, Civalero and Burry2021). Human coprolites and those of other large mammals are often big enough to be subdivided such that each coprolite subsample is used for a different analysis or for a repetition of the same analysis, and much discussion concerns optimal subsampling strategies (Beck et al. Reference Beck, Bryant and McDonough2019). Another standard procedure in coprolite studies is removal of the outer surface to reduce contamination (Wood and Wilmshurst Reference Wood and Wilmshurst2016). However, these procedures present problems for multi-proxy analysis of individual livestock coprolites, particularly sheep/goat pellets, which are the most common type of dung in “Old-World” archaeology, and which have added research value as indicators of rangeland vegetation, seasonality, and pastoral practices (Akeret et al. Reference Akeret, Haas, Leuzinger and Jacomet1999; Ghosh et al. Reference Ghosh, Gupta, Bera, Jiang, Li and Li2008; Fuks and Dunseth Reference Fuks and Dunseth2021).

First, subdividing individual sheep/goat pellets for different analyses may sacrifice representativeness to the point of being counterproductive. Second, removing the outer surface significantly reduces the size of the starting sheep/goat pellet sample (as shown in this study), leaving even less material for subsampling and analysis. One solution is to maximize the number of analyses that can be applied in series to a single pellet. Thus, non-destructive analyses (description, weighing, imaging, NIR spectroscopy), could be followed by semi-destructive analyses (dissecting for plant macrofossils, FTIR spectroscopy) and fully destructive analyses in turn (pollen, phytolith, dietary fiber, lipid, protein, and DNA analyses). Yet this still leaves the sizable outer surface as unusable discard. Meanwhile, the richer and more interesting the information gleaned from coprolite analyses, the greater the need to establish its antiquity through direct radiocarbon dating. This creates a third problem in adopting a multi-proxy approach: there is no guarantee that an individual sheep/goat dung pellet can be directly dated and subjected to additional destructive analyses. Thus, a priori subdivision of individual caprine pellets for radiocarbon and other analyses risks sacrificing this scarce resource and producing no results.

We addressed these problems by exploring possibilities for minimally destructive radiocarbon dating of sheep/goat dung pellets preserved by desiccation in Israel’s Negev desert. Our primary research question was, how can an individual caprine pellet be chronometrically dated while preserving as much of it as possible for additional analyses? To answer this question, we conducted experiments on standard pretreatments used in radiocarbon analysis applied to desiccated dung pellets from three archaeological sites in the region. Our ultimate objective was to achieve minimally destructive reliable radiocarbon dating of dung pellet samples. The following specific research questions guided the experimental design:

  • Which sample-specific factors are related to pretreatment losses and survivability?

  • Which pretreatment (acid-alkali-acid or acid-only) best balances survivability and reliability?

  • What is a minimal dung sample start weight for reliable radiocarbon dating?

  • Can shavings of a coprolite’s outer surface be used to produce a reliable date?

METHODS

Sample Retrieval and Preparation

Analyzed coprolites derived from three sites in the Negev desert, Israel: Avdat (Oboda, Abde); Orhan Mor (Moyat Awad) and Nahal Omer (Table 1). The copious dung remains from these sites were variously preserved, often in semi-compacted dung layers or pulverized. We selected only uncharred intact pellets for analysis.

Table 1 Sample sites and contexts.

Archaeological coprolites from Avdat were retrieved in the 2016 excavation of the Avdat in Late Antiquity Project by Scott Bucking and Tali Erickson-Gini, which yielded hundreds of dung pellets (Bucking Reference Bucking2017; Bucking and Erickson-Gini Reference Bucking and Erickson-Gini2020; Bucking et al. Reference Bucking, Fuks, Dunseth, Schwimer and Erickson-Gini2022; Erickson-Gini Reference Erickson-Gini2022). The particular coprolite assemblage used in this study was preserved by desiccation and comes from a sealed collapse layer dated to the late-medieval, or local Late Islamic period (Table 1, Figure 1) by whole sheep/goat dung pellet (UBA-47071, 418 ± 22 BP, 1σ 1445–1470 cal CE; following acid-only pretreatment). In addition, modern dung pellets collected by the author (D.F.) in 2018 from the ground of Avdat’s acropolis were used in the first batch of pretreatment experiments.

Figure 1 Sheep/goat dung pellets from the late-medieval Avdat assemblage (OBD-2016-L101-B4).

Coprolites from Orhan Mor and Nahal Omer were retrieved by the author (D.F.) in February 2022 during the Negev Camel Caravan Project excavation headed by Guy Bar-Oz and Roy Galili (Galili et al. Reference Galili, Avni, Tepper, Erickson-Gini, Shamir, Bar-Oz, Ben David and Perry2021; Bar-Oz et al. Reference Bar-Oz, Galili, Fuks, Erickson-Gini, Tepper, Shamir and Avni2022). The Nahal Omer pellets appeared exceptionally preserved by desiccation and derive from two different Early Islamic rubbish middens: Areas A and B of the 2020 excavations. The Orhan Mor coprolites come from a small hillside mixed organic assemblage whose ceramics suggest a 3rd c. CE terminus, or the local Roman period. Unlike the other contexts, however, this one was not well-stratified or sealed, and a later intrusion of dung pellets cannot be ruled out.

Over 100 pellets and pellet fragments from these contexts were individually prepared in the Pitt Rivers Laboratory of the McDonald Institute for Archaeological Research at the University of Cambridge. Each pellet/fragment was individually weighed and photographed, and observations of external preservation and color were recorded (Figure 2; Supplementary Table 1). Shaving of the outer surface, including any folds or cracks in contact with the encasing sediment, was performed on some of the fully intact pellets (Figure 3). This was conducted manually with a scalpel and tweezers, and all equipment was sprayed and wiped between pellets with an ammonium-chloride-based laboratory disinfectant. External shavings and the remaining inner part were stored in separate glass vials for each pellet and labeled accordingly.

Figure 2 Intact sheep/goat dung pellet from late-medieval Avdat (OBD-2016-L101-B4-P8).

Figure 3 Outer shavings (left) and the remaining inner part (right) of a sheep/goat dung pellet from late-medieval Avdat (OBD-2016-L101-B4-P8-ex and OBD-2016-L101-B4-P8-in).

Pretreatment

Samples were brought to the 14CHRONO Centre for Climate, the Environment & Chronology at Queen’s University, Belfast, where they were further selected from among the originally intact pellets for pretreatment experiments (Supplementary Table 2). Shaving of the outer surfaces was performed on additional select pellets. Acid-alkali-acid (AAA) pretreatment was selected for Batches 1–3 because the alkali step removes potentially contaminating humic acids whereas acid-only pretreatment removes only carbonates. AAA consisted of the following steps:

  • Acid – Sample placed in a polypropylene 50-mL test-tube solution of 0.1M HCl. Test-tubes placed in 80°C bath for 20 minutes.

  • Centrifuge and wash – Test-tubes centrifuged using a SciQuip Sigma 4–5-L centrifuge at 3000 revloutions/min for 3 min. Supernatant fluid decanted and pellet/precipitate retained. Tubes then filled with deionized water, spun, and decanted 3 more times.

  • Alkali – 25 mL of 0.25M NAOH solution in 80ºC bath.

  • Centrifuge and wash – same as above. Note: Only one alkali rinse was needed as little color was removed in these samples.

  • Acid – 1M HCl, 80ºC bath for 20 min.

  • Centrifuge and wash – same as above.

  • Drying – Samples were dried overnight at 75ºC.

In Batch 1, AAA pretreatments were conducted on six pairs of modern pellet samples (from OBD-rec-2018), where each pair included the external shavings and the remaining inner part of the pellet (Pex and Pin). Preliminary observations at the alkali stage suggested sufficient survivability to continue using AAA.

In Batch 2, the experiment was repeated for one pair of late-medieval Avdat external pellet shavings (OBD-2016-L101-B4-P7-ex) and inner pellet (OBD-2016-L101-B4-P7-in). External shavings of five pellets from Roman(?) Orhan Mor (MOA-2020-L630-B6304) and five pellets from Early Islamic Nahal Omer, Area B (OMR-2020-L203-B2031a) were also tested. Preliminary observations at the Alkali stage suggested insufficient survivability for the Orhan Mor samples.

In Batch 3, a pair of external and internal pellet samples from an upper layer of Early Islamic Nahal Omer, Area A (OMR-2020-L103-B10033b) and from a lower layer (OMR-2020-L107-B17001) were tested with AAA pretreatment. Another pair of external and internal pellet samples from late-medieval Avdat (OBD-2016-L101-B4-P8-ex and OBD-2016-L101-B4-P8-in) was also tested.

In Batch 4, three pairs of whole pellets were selected from Orhan Mor and Nahal Omer to compare loss from acid-only against AAA pretreatments. These were performed with the same solutions described above but without hot baths.

Data was collected on start weights and end weights after drying for all samples, and qualitative observations of color and fibrousness were additionally considered to predict whether sufficient carbon content remained for radiocarbon measurement by AMS (Supplementary Table 2).

AMS Dating

In order to test the reliability of dates retrieved from the outer surface of dung pellets, we dated eight samples from Batches 2 and 3 consisting of external shavings and the remaining inner part for four pellets (Table 2):

Table 2 Samples dated from Batches 2 and 3.

As a guide to the labeling system used below note that OBD-2016-L101-B4-P8, for example, refers to dung pellet 8 from Locus 101, Basket 4, of the 2016 Avdat (Oboda) excavations (see also Table 1). OBD-2016-L101-B4-P8-ex refers to that pellet’s external shavings whereas OBD-2016-L101-B4-P8-in refers to its inner part (Figure 3).

The dried samples were weighed in pre-purified tin capsules and burned in oxygen with helium carrier gas in the element analyzer (Elementar Vario Isotope), then transferred to the AGE3 automated graphitization system, which uses the hydrogen reduction method (Němec et al. Reference Němec, Wacker and Gäggeler2010). The prepared graphite was compressed into vacuum-cleaned aluminum holders and placed in an AMS magazine. The ratios 14C/12C and 13C/12C were measured using accelerator mass spectrometry (AMS) in the Ionplus Mini Carbon Dating System (MICADAS). The sample 14C/12C ratio was background corrected and normalised to the HOXII standard (SRM 4990C; National Institute of Standards and Technology). The radiocarbon ages were corrected for isotope fractionation using the AMS measured δ13C which accounts for both natural and machine fractionation. The radiocarbon age and one standard deviation were calculated using the Libby half-life of 5568 years following the methods of Stuiver and Polach (Reference Stuiver and Polach1977).

RESULTS

Outer Shavings

Weights of the original intact pellets (P) and of the external shavings (Pex) of 20 pellets used in this study appear in Table 3. The proportion of the external shavings’ weight over whole pellet weight (Pex/P), ranged from 18% to 64% with a mean of 37% and a standard deviation of 11% (n=20). These values varied among sample groups: For all recent and late-medieval pellets from Avdat, Pex/P was under 35% whereas for all Early Islamic pellets from Orhan Mor it was above 35%. Three pellets from Orhan Mor had Pex/P values of above 45% whereas the remaining two from Orhan Mor were 37% and 42%. Pex/P ranged from 30–45% for all Nahal Omer pellets. These results reflect observed sample-specific differences in whole pellet preservation quality. In most of the recent pellets, the outer layer could be peeled off with the scalpel, whereas the Orhan Mor pellets had a tendency to crumble. Pellets from Nahal Omer and late-medieval Avdat were fairly rigid but not as easily shaven as the recent pellets.

Table 3 Weights of whole pellets and external shavings.

Pretreatment

Figure 4 presents weight loss due to pretreatment by sample (see also Supplementary Tables 34). Of 37 pretreated samples, two yielded end weights larger than those of the original sample and were rejected as measuring or recording errors. Of the samples undergoing AAA pretreatment, weight-loss ranged from 58–100%, with a mean of 78% and standard deviation of 13% (n=32). As with the external shavings’ relative weights, weight losses due to pretreatment varied by assemblage:

Figure 4 Loss from pretreatment by start weight.

For the recent Avdat pellet samples used in Batch 1, weight losses ranged from 58–76%, with a mean of 65% and standard deviation of 6% (n=10; based on 6 inner pellets and 4 associated external shavings). To formulate a working assumption regarding minimum datable sample size, we used a previously AMS-dated late-medieval Avdat dung pellet (UBA-47071) where carbon content measured 60.54% (Table 4). At this carbon content, we estimated a minimum sample weight for radiocarbon dating following pretreatment as 1 mg for compatibility with the AGE3 regular sample size setup, but we considered 2–4 mg to be preferable in the event of higher weight loss in pretreatment. In Batch 1, end weights were all well above this threshold (≥ 20 mg) and we therefore continued to experiment with AAA pretreatment in Batches 2 and 3. However, subsequent batches displayed different pretreatment survivability ranges and means, which varied according to site and starting weight.

Table 4 AMS dates from dung pellets and Chi-squared test for external-internal pellet pairs.

A final factor observed to affect pretreatment survivability is starting weight. Pretreatment losses by starting weight appear in Figure 4. All samples with start weights >200 mg exhibited weight losses <70%, while all weight losses >90% derived from samples with start weights <100 mg.

Four late-medieval Avdat pellet sample losses ranged from 63–79%, within the range of the recent Avdat pellets. By contrast, pellets from Orhan Mor undergoing AAA pretreatment had effective total losses in four out of five AAA pretreatments (≥97%, with end weights of 0.001 g or less). In the fifth sample, an 80% loss was recorded, with 16 mg remaining out of the initial 82 mg. However, on inspection with a stereo microscope the surviving material appeared to be almost entirely composed of quartz granules with a couple pieces of microcharcoal, and the sample was deemed non-datable.

Nahal Omer pellet samples fared in between the Orhan Mor and Avdat pellets, with a range of 68–95% losses due to AAA pretreatment, a mean of 84% and standard deviation of 8% (n=12). End weights ranged from 4–28 mg for the external shavings (n=7) and 18–51 mg for the inner pellets (n=3). The surviving material was light yellow in color and appeared to be highly fibrous under the stereo microscope.

We observed that washing of samples with deionized water after each pretreatment stage accounts for some of these losses, especially among the lighter samples. However, most loss appeared to have occurred at the alkali stage of pretreatment. This suggested that acid-only would yield lower losses. To test this hypothesis, we compared acid-only to AAA pretreatments on pairs of pellets from three different assemblages in Batch 4, one from Orhan Mor and two from Nahal Omer. Each pair consisted of two pellets from the same archaeological locus-basket, where one whole pellet underwent acid-only pretreatment and the other underwent AAA (Figure 5). Comparison of weight losses demonstrates much greater loss under AAA: for the Orhan Mor pair, loss was 87% under AAA compared with 68% under acid-only. For the Nahal Omer pairs, losses were 74% and 68% under AAA compared with only 39% for each of the two acid-only treated pellets.

Figure 5 Dried results of whole pellet pretreatment in acid-only (left) and AAA (right). Dung pellets shown come from Orhan Mor (MOA-2020-L630-B6304-P9 and MOA-2020-L630-B6304-P10).

AMS Dating

To test the reliability of radiocarbon-dating external pellet shavings, pairs of AAA pretreated inner and external pellet were separately dated by AMS from four pellets. None of the Orhan Mor pellet external shavings were deemed datable due to pretreatment weight losses and observations of surviving content. Samples were drawn from each of the four remaining archaeological loci used in this study, including one pellet from late-medieval Avdat and three from Early Islamic Nahal Omer (see Tables 1 and 4). Carbon content ranged from 21.15%–50.27%. In each case, the radiocarbon date obtained from the external shavings closely matched that obtained from the inner part of the same pellet, and all pairs pass the chi-squared test at 95% confidence level (Table 4). Although dated at a preliminary stage using acid-only pretreatment, data for UBA 47071 is presented at the end of Table 4 for comparison with the other late-medieval Avdat pellet (UBA 47567, 47568). Unlike the other samples, weight presented for UBA 47071 refers to its whole pellet weight prior to pretreatment.

DISCUSSION

Information obtained from each of the three stages of this study offers useful insights for radiocarbon dating of coprolites. This has particular relevance to minimally destructive analysis of sheep/goat dung pellets. We discuss findings from each stage.

Outer Shavings

Data on relative weights of external shavings suggest that the proportion of pellet weight lost from removing the outer layer to avoid contaminants is on the order of ⅓ to ½ for ancient sheep/goat pellets. This is a significant proportion of the dung pellet which is lost in rigorous coprolite analysis and can probably only be reduced slightly through finer instrumentation. This certainly justifies checking whether such external coprolite shavings can be reliably used for any component of multi-proxy analysis. Differences between samples in the proportion of pellet weight lost from removing the outer layer are related to coprolite preservation quality and might be used as a proxy for general preservation. Qualitatively speaking, we observed that the way a pellet sample performs under handling at this stage may indicate how it will perform in pretreatments and subsequent analyses.

Pretreatment

Pretreatment weight loss of dung pellet samples was found to be correlated with start weight (Spearman rank correlation ρ = 0.763) and with site (Figure 4). Variation in sample loss according to site and start weight may well be linked to a third common factor, namely, preservation. Preservation in this sense is a qualitative factor based on observable characteristics. Visible traits which we associate with good preservation include a minimum of nicks and dents in the pellet, pellet rigidity, lightness of color, visible fibers and a greater propensity for macroscopic plant remains within the pellet. Poorly preserved pellets are associated with external nicks and dents, a greater propensity to crumble under light pressure, darker hue, few or no visible plant remains, and a sandier rather than fibrous internal structure.

Using these criteria, the best-preserved study samples were the recent pellets from Avdat, which were also the heaviest and exhibited the lowest losses in these experiments. Hence, we cannot disentangle their start weight and preservation quality as factors affecting percent loss. On the other hand, Orhan Mor pellets were generally lighter than the rest, their preservation was observably poorer with a sandy texture, no visible fiber and a tendency to crumble, and their losses due to pretreatments were higher than samples of comparable start weight from Nahal Omer. These findings support the observation made by Dunseth et al. (Reference Dunseth, Fuks, Langgut, Weiss, Butler, Yan, Boaretto, Tepper, Bar-Oz and Shahack-Gross2019) that weight may be a proxy for organic preservation in dung pellets. Nevertheless, one way that small starting weight independently contributes to high percentage losses during pretreatment is through the greater suspension of light crushed pellet solids in water during the washing stages, which are poured out. In theory, additional centrifuging or longer settling times for suspended particles could help, but this is usually impractical in a busy radiocarbon lab. Instead, pellet weight and observations of preservation quality such as internal fibrousness, may be used to select pellets for radiocarbon dating.

The differences between weight losses under acid-only and AAA pretreatments in Batch 4 demonstrate that the greatest losses resulted from the alkali stage. This indicates the presence of undigested biomolecular compounds such as plant waxes, lipids and proteins as well as potentially some humic acids, despite the dry conditions. We would expect the plant-derived compounds to have been consumed as part of the diet and therefore unlikely to be a concern for radiocarbon dating. However, humic acids can be derived from younger, or occasionally older, organic material in sediments, which can affect radiocarbon measurements. Indeed, the date obtained from an acid-only pretreated whole pellet from late-medieval Avdat (418 BP ± 22) was older by about 100 14C yrs when compared to the AAA pretreated samples from the same assemblage (Table 4). This suggests the importance of using alkali as part of pretreatments for dung pellets. The effect of either humic acids or biomolecular compounds on stable isotope analysis should be considered. C:N measurements may be useful indicators of the presence of these additional sources of carbon.

AMS Dating

We found that AMS radiocarbon dating of external pellet shavings yielded essentially the same results as dating the inner part of the same pellet. This is significant because coprolites’ outer surfaces are removed and discarded to reduce contamination in other analyses (e.g., pollen, phytolith, sedimentary and biomolecular analyses) because the extraction process would not remove the contaminating material. Our findings show that external pellet shavings may be reliably used for radiocarbon dating, at least for some assemblages, as most contamination would be removed by the AAA pretreatment.

By capitalizing on this otherwise useless coprolite component, reliable radiocarbon dating can be performed without sacrificing material used in other analyses, presenting a new addition to multi-proxy coprolite analysis workflows. Future research on minimally destructive coprolite dating could investigate the taphonomic mechanisms underlying carbon preservation in dung pellets, in concert with soil chemistry and micromorphology. First, if reliable radiocarbon measurements can be obtained from external shavings, can other isotopic measurements be reliably obtained from the same source? Second, more experiments could be performed to quantify the significance of humic acids and the differences between coprolite radiocarbon dates after acid-only versus AAA pretreatments. Meanwhile, our success in dating external shavings which underwent AAA pretreatment suggests a practical yet ideal protocol in which rigorous pretreatment is applied in the radiocarbon dating of an otherwise useless coprolite component. The main thing to test in the future is its applicability to a wider variety of samples and contexts.

CONCLUSIONS

This study enabled us to answer the following research questions concerning minimally destructive radiocarbon dating of sheep/goat dung pellets, based on samples from archaeological sites in the Negev desert:

Which sample-specific factors are related to pretreatment losses and survivability?

Site and start weight were correlated with weight-based pretreatment survivability. In addition, observable preservation features—including external surface, rigidity, color, fibers and other macroscopic plant remains within—appear to be correlated with survivability.

Which pretreatment (AAA or acid-only) best balances survivability and reliability?

Our results demonstrate that AAA can be used as a pretreatment for sheep/goat dung pellets, above a certain minimal start weight. Acid-only pretreatment is less destructive but should only be used after humic acid contamination is ruled out.

What is a minimal dung sample start weight for reliable radiocarbon dating?

Our results suggest that an initial weight of 100 mg is a desirable minimum threshold for dating samples of sheep/goat dung from the Negev desert.

Can outer shavings of dung pellets be used to produce a reliable date?

Yes. Our findings indicate that it is just as reliable to date the external shavings of a dung pellet as it is to date the remaining inner pellet. This suggests an important addition to multi-proxy coprolite analysis workflows, certainly for Negev sheep/goat dung pellets, and likely for those of other regions and species.

SUPPLEMENTARY MATERIAL

To view supplementary material for this article, please visit https://doi.org/10.1017/RDC.2023.70

ACKNOWLEDGMENTS

This research was funded by a Cambridge Humanities and Research Grant and a Newton International Fellowship awarded to D.F.

AUTHOR CONTRIBUTIONS

D.F., N.O.M. and P.J.R. designed the research. D.F. and N.O.M. conducted the experiments. D.F. wrote the manuscript with substantial contributions by N.O.M. and P.J.R. Samples and information on archaeological context were provided by T.E.G., S.B., R.G. and G.B.O.

COMPETING INTERESTS DECLARATION

The authors declare that there are no competing interests associated with this paper.

References

REFERENCES

Akeret, O, Haas, JN, Leuzinger, U, Jacomet, S. 1999. Plant macrofossils and pollen in goat/sheep faeces from the Neolithic lake-shore settlement Arbon Bleiche 3, Switzerland. Holocene 9(2):175182.Google Scholar
Baeten, J, Mees, F, Marinova, E, de Dapper, M, de Vos, D, Huyge, D, van Strydonck, M, Vandenberghe, D, Linseele, V. 2018. Late Pleistocene coprolites from Qurta (Egypt) and the potential of interdisciplinary research involving micromorphology, plant macrofossil and biomarker analyses. Review of Palaeobotany and Palynology 259:93111. https://doi.org/10.1016/j.revpalbo.2018.09.014 Google Scholar
Bar-Oz, G, Galili, R, Fuks, D, Erickson-Gini, T, Tepper, Y, Shamir, N, Avni, G. 2022. Caravanserai middens on desert roads: a new perspective on the Nabataean–Roman trade network across the Negev. Antiquity 96(387):592610. https://doi.org/10.15184/aqy.2022.40 Google Scholar
Beck, CW, Bryant, VM, McDonough, KN. 2019. Evidence for non-random distribution of pollen in human coprolites. Archaeological and Anthropological Sciences 11(11):59835998. https://doi.org/10.1007/s12520-019-00839-y Google Scholar
Bucking, S. 2017. A dipinti-intensive cave dwelling as evidence of a monastic presence in Byzantine Avdat. Journal of Arid Environments 143:2834. https://doi.org/10.1016/j.jaridenv.2016.11.008 CrossRefGoogle ScholarGoogle Scholar
Bucking, S, Erickson-Gini, T. 2020. The Avdat in Late Antiquity Project: report on the 2012/2016 excavations of a cave and stone-built compound along the southern slope. Journal of Eastern Mediterranean Archaeology and Heritage Studies 8:2257. https://doi.org/10.5325/jeasmedarcherstu.8.1.0022 Cross RefGoogle ScholarGoogle Scholar
Bucking, S, Fuks, D, Dunseth, Z, Schwimer, L, Erickson-Gini, T. 2022. The Avdat in Late Antiquity Project: Uncovering the Early Islamic phases of a Byzantine town in the Negev Highlands. Antiquity 96(387):754761. https://doi.org/10.15184/aqy.2022.46 Google Scholar
Camacho, M, Araújo, A, Morrow, J, Buikstra, J, Reinhard, K. 2018. Recovering parasites from mummies and coprolites: an epidemiological approach. Parasites & Vectors 11(1):117. https://doi.org/10.1186/s13071-018-2729-4 Google Scholar
Delhon, C, Martin, L, Argant, J, Thiébault, S. 2008. Sheperds and plants in the Alps: multi-proxy archaeobotanical analysis of Neolithic dung from “La Grande Rivoire” (Isère, France). Journal of Archaeological Science 35:29372952. http://doi.org/10.1016/j.jas.2008.06.007 Google Scholar
di Lernia, S. 2001. Dismantling dung: delayed use of food resources among early Holocene foragers of the Libyan Sahara. Journal of Anthropological Archaeology 20(4):408441. https://doi.org/10.1006/jaar.2000.0384 Google Scholar
Dunseth, Z, Fuks, D, Langgut, D, Weiss, E, Butler, D, Yan, X, Boaretto, E, Tepper, Y, Bar-Oz, G, Shahack-Gross, R. 2019. Archaeobotanical proxies and archaeological interpretation: a comparative study of phytoliths, seeds and pollen in dung pellets and refuse deposits at Early Islamic Shivta, Negev, Israel. Quaternary Science Reviews 211:166185. http://doi.org/10.1016/j.quascirev.2019.03.010 Google Scholar
Égüez, N, Makarewicz, CA. 2018. Carbon isotope ratios of plant n-alkanes and microstratigraphy analyses of dung accumulations in a pastoral nomadic winter campsite (eastern Mongolia). Ethnoarchaeology 10(2):141158. https://doi.org/10.1080/19442890.2018.1510614 Google Scholar
Erickson-Gini, T. 2022. Evidence of a Late Byzantine Period earthquake and a monastic stable at ‘Avedat (Oboda). ‘Atiqot 107:153198.Google Scholar
Fuks, D, Dunseth, Z. 2021. Dung in the dumps: what we can learn from multi-proxy archaeobotanical study of herbivore dung pellets. Vegetation History and Archaeobotany 30:137153. https://doi.org/10.1007/s00334-020-00806-x Google Scholar
Galili, R, Avni, G, Tepper, Y, Erickson-Gini, T, Shamir, N, Bar-Oz, G. 2021. News from the dumps: preliminary observations from the Camel Caravan Project along the Incense Route in the Negev and Arava (Hebrew). In: Ben David, H, Perry, D, editors. The Incense Route 2021. Jerusalem: Dan Perry. p. 189204.Google Scholar
Ghosh, R, Gupta, S, Bera, S, Jiang, HE, Li, X, Li, CS. 2008. Ovi-caprid dung as an indicator of paleovegetation and paleoclimate in northwestern China. Quaternary Research 70(2):149157. https://doi.org/10.1016/j.yqres.2008.02.007 Google Scholar
Hunt, AP, Milàn, J, Lucas, SG, Spielmann, JA, editors. 2012. Vertebrate coprolites. New Mexico Museum of Natural History and Science. p. 153160.Google Scholar
Jouy-Avantin, F, Debenath, A, Moigne, AM, Moné, H. 2003. A standardized method for the description and the study of coprolites. Journal of Archaeological Science 30(3):367372. https://doi.org/10.1006/jasc.2002.0848 Google Scholar
Kühn, M, Maier, U, Herbig, C, Ismail-Meyer, K, Le Bailly, M, Wick, L. 2013. Methods for the examination of cattle, sheep and goat dung in prehistoric wetland settlements with examples of the sites Alleshausen-Täschenwiesen and Alleshausen-Grundwiesen (around cal 2900 BC) at Lake Federsee, south-west Germany. Environmental Archaeology 18(1):4357. https://doi.org/10.1179/1461410313Z.00000000017 Google Scholar
Landau, SY, Dvash, L, Ryan, P, Saltz, D, Deutch, T, Rosen, SA. 2020. Faecal pellets, rock shelters, and seasonality: The chemistry of stabling in the Negev of Israel in late prehistory. Journal of Arid Environments 181:104219. https://doi.org/10.1016/j.jaridenv.2020.104219 Google Scholar
Linseele, V, Riemer, H, Baeten, J, De Vos, D, Marinova, E, Ottoni, C. 2013. Species identification of archaeological dung remains: a critical review of potential methods. Environmental Archaeology 18(1):517. https://doi.org/10.1179/1461410313Z.00000000019 Google Scholar
Marinova, E, Ryan, P, Van Neer, W, Friedman, R. 2013. Animal dung from arid environments and archaeobotanical methodologies for its analysis: An example from animal burials of the Predynastic elite cemetery HK6 at Hierakonpolis, Egypt. Environmental Archaeology 18(1):5871. https://doi.org/10.1179/1461410313Z.00000000020 Google Scholar
Miller, NF. 1984. The use of dung as fuel: an ethnographic example and an archaeological application. Paléorient 10(2):7179.CrossRefGoogle Scholar
Němec, M, Wacker, L, Gäggeler, H. 2010. Optimization of the graphitization process at AGE-1. Radiocarbon 52:13801393. https://doi.org/10.1017/S0033822200046464 Google Scholar
Perrotti, AG, van Asperen, E. 2019. Dung fungi as a proxy for megaherbivores: opportunities and limitations for archaeological applications. Vegetataion History and Archaeobotany 28:93104. https://doi.org/10.1007/s00334-018-0686-7 Google Scholar
Pineda, A, Saladié, P, Expósito, I, Rodríguez-Hidalgo, A, Cáceres, I, Huguet, R, Rosas, A, López-Polín, L, Estalrrich, A, García-Tabernero, A, Vallverdú, J. 2017. Characterizing hyena coprolites from two latrines of the Iberian Peninsula during the Early Pleistocene: Gran Dolina (Sierra de Atapuerca, Burgos) and la Mina (Barranc de la Boella, Tarragona). Palaeogeography, Palaeoclimatology, Palaeoecology 480:117. https://doi.org/10.1016/j.palaeo.2017.04.021 Google Scholar
Poinar, HN, Hofreiter, M, Spaulding, WG, Martin, PS, Stankiewicz, BA, Bland, H, Evershed, RP, Possnert, G, Pääbo, S. 1998. Molecular coproscopy: dung and diet of the extinct ground sloth Nothrotheriops shastensis. Science 281:402406. https://doi.org/10.1126/science.281.5375.402 Google Scholar
Polling, M, ter Schure, AT, van Geel, B, et al. 2021. Multiproxy analysis of permafrost preserved faeces provides an unprecedented insight into the diets and habitats of extinct and extant megafauna. Quaternary Science Reviews 267:107084. https://doi.org/10.1016/j.quascirev.2021.107084 Google Scholar
Qvarnström, M, Niedźwiedzki, G, Žigaitė, Ž. 2016. Vertebrate coprolites (fossil faeces): an underexplored Konservat-Lagerstätte. Earth-Science Reviews 162:4457. https://doi.org/10.1016/j.earscirev.2016.08.014 Google Scholar
Reinhard, KJ, Bryant, VM. 1992. Coprolite analysis: a biological perspective on archaeology. Archaeological Method and Theory 4:245288.Google Scholar
Rifkin, RF, Vikram, S, Ramond, JB, et al. 2020. Multi-proxy analyses of a mid-15th century Middle Iron Age Bantu-speaker palaeo-faecal specimen elucidates the configuration of the “ancestral” sub-Saharan African intestinal microbiome. Microbiome 8:62. https://doi.org/10.1186/s40168-020-00832-x Google Scholar
Romaniuk, AA, Panciroli, E, Buckley, M. et al. 2020. Combined visual and biochemical analyses confirm depositor and diet for Neolithic coprolites from Skara Brae. Archaeol Anthropol Sci 12:274. https://doi.org/10.1007/s12520-020-01225-9 Google Scholar
Shahack-Gross, R. 2011. Herbivorous livestock dung: formation, taphonomy, methods for identification, and archaeological significance. Journal of Archaeological Science 38:205218. https://doi.org/10.1016/j.jas.2010.09.019 Google Scholar
Shillito, LM, Blong, JC, Green, EJ, van Asperen, EN. 2020. The what, how and why of archaeological coprolite analysis. Earth-Science Reviews 207:103196. https://doi.org/10.1016/j.earscirev.2020.103196 Google Scholar
Sistiaga, A, Mallol, C, Galván, B, Summons, RE. 2014. The Neanderthal meal: a new perspective using faecal biomarkers. PloS One 9(6):p.e101045. https://doi.org/10.1371/journal.pone.0101045 Google Scholar
Stuiver, M, Polach, HA. 1977. Discussion: reporting of C-14 data. Radiocarbon 19:355–63. https://doi.org/10.1017/S0033822200003672 Google Scholar
Velázquez, NJ, Tosto, ACM, Benvenuto, ML, Fernández, N, Civalero, MT, Burry, LS. 2021. Multiproxy analysis of omnivore and herbivore coprolites: inferences on Mid-Holocene dietary habits in Argentine Patagonia. Quaternary International 601:130142. https://doi.org/10.1016/j.quaint.2021.06.029 Google Scholar
Wood, JR, Wilmshurst, JM. 2016. A protocol for subsampling Late Quaternary coprolites for multi-proxy analysis. Quaternary Science Reviews 138:15. https://doi.org/10.1016/j.quascirev.2016.02.018 Google Scholar
Wood, JR, Richardson, SJ, McGlone, MS, Wilmshurst, JM. 2020. The diets of moa (Aves: Dinornithiformes). New Zealand Journal of Ecology 44(1):121. https://dx.doi.org/10.20417/nzjecol.44.3 Google Scholar
Zhang, Y, van Geel, B, Gosling, WD, McMichael, CNH, Jansen, B, Absalah, S, Sun, G, Wu, X, 2019. Local vegetation patterns of a Neolithic environment at the site of Tianluoshan, China, based on coprolite analysis. Review of Palaeobotany and Palynology 271:104101. https://doi.org/10.1016/j.revpalbo.2019.104101 Google Scholar
Figure 0

Table 1 Sample sites and contexts.

Figure 1

Figure 1 Sheep/goat dung pellets from the late-medieval Avdat assemblage (OBD-2016-L101-B4).

Figure 2

Figure 2 Intact sheep/goat dung pellet from late-medieval Avdat (OBD-2016-L101-B4-P8).

Figure 3

Figure 3 Outer shavings (left) and the remaining inner part (right) of a sheep/goat dung pellet from late-medieval Avdat (OBD-2016-L101-B4-P8-ex and OBD-2016-L101-B4-P8-in).

Figure 4

Table 2 Samples dated from Batches 2 and 3.

Figure 5

Table 3 Weights of whole pellets and external shavings.

Figure 6

Figure 4 Loss from pretreatment by start weight.

Figure 7

Table 4 AMS dates from dung pellets and Chi-squared test for external-internal pellet pairs.

Figure 8

Figure 5 Dried results of whole pellet pretreatment in acid-only (left) and AAA (right). Dung pellets shown come from Orhan Mor (MOA-2020-L630-B6304-P9 and MOA-2020-L630-B6304-P10).

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