Journal of Archaeological Method and Theory

, Volume 24, Issue 3, pp 776–795 | Cite as

Exploring Accumulation Rates of Shell Deposits Through Seasonality Data

Article

Abstract

Shell middens are often analysed as the result of short- or long-term depositional activities. In order to confidently interpret such deposits, it is necessary to have accurate estimations of shell accumulation rates, most commonly produced by radiocarbon dates. This paper introduces the application of seasonality data as a temporal measurement of short-term shell deposition. This gives access to an additional estimate of shell accumulation rates, which work on a shorter timescale than can be analysed through radiocarbon dating. We focus on shell deposits on the Farasan Islands, Saudi Arabia, which comprise over 3000 shell midden sites dating to the mid-Holocene (6500–4500 calBP). One site (JW1727) was chosen to (1) explore the potential of seasonality data to reconstruct accumulation rates, (2) analyse the intensity of exploitation and (3) assess the visibility of short-term shellfish deposits. Stable oxygen isotope values (δ18O) were obtained from the marine gastropod Conomurex fasciatus (Born 1778), representing 72 % of the shell weight of JW1727, to reconstruct season of capture. Seasonality data was grouped by their spatial distribution, which allowed successive episodes of deposition within a stratigraphic sequence to be connected. This allowed us to make an estimation of exploited shell meat of ∼200 kg over a 7-month period (∼400 shells/day). We argue that excavation methods and low resolution stratigraphic data cause imprecision in the seasonality data and the low visibility of rapidly accumulated shell deposits. Also, an increase of analysed shells per layer is key to understanding the seasonal brickwork of more middens in the future.

Keywords

Shell midden Accumulation Seasonality Feasting Farasan Stable isotopes 

Supplementary material

10816_2016_9287_MOESM1_ESM.docx (60 kb)
ESM 1(DOCX 60 kb)
10816_2016_9287_MOESM2_ESM.xlsx (203 kb)
ESM 2(XLSX 203 kb)

References

  1. Bailey, G. (2007). Time perspectives, palimpsests and the archaeology of time. Journal of Anthropological Archaeology, 26, 198–223.CrossRefGoogle Scholar
  2. Bailey, G.N., Meredith-Williams, M., Alsharekh, A.M. (2013). Shell mounds of the Farasan Islands, Saudi Arabia, in: Bailey, G.N., Hardy, K., Camara, A. (Eds.), Shell Energy:241–254.Google Scholar
  3. Bayliss, A. (2015). Quality in Bayesian chronological models in archaeology. World Archaeology, 47, 677–700.CrossRefGoogle Scholar
  4. Briz Godino, I., Álvarez, M., Balbo, A., Zurro, D., Madella, M., Villagrán, X., & French, C. (2011). Towards high-resolution shell midden archaeology: experimental and ethnoarchaeology in Tierra del Fuego (Argentina). Quaternary International, 239, 125–134.CrossRefGoogle Scholar
  5. Bronk Ramsey, C., & Lee, S. (2013). Recent and planned developments of the program OxCal. Radiocarbon, 55(2–3), 720–730.CrossRefGoogle Scholar
  6. Buck, C. E., & Meson, B. (2015). On being a good Bayesian. World Archaeology, 47, 567–584.CrossRefGoogle Scholar
  7. Burchell, M., Hallmann, N., Martindale, A., Cannon, A., & Schöne, B. R. (2013). Seasonality and intensity of shellfish harvesting on the north coast of British Columbia. The Journal of Island and Coastal Archaeology, 8, 152–169.CrossRefGoogle Scholar
  8. Claassen, C. (1998). Shells. Cambridge University Press.Google Scholar
  9. Colonese, A. C., Verdún-Castelló, E., Álvarez, M., Briz i Godino, I., Zurro, D., & Salvatelli, L. (2012). Oxygen isotopic composition of limpet shells from the Beagle Channel: implications for seasonal studies in shell middens of Tierra del Fuego. Journal of Archaeological Science, 39, 1738–1748.CrossRefGoogle Scholar
  10. Culleton, B. J., Kennett, D. J., & Jones, T. L. (2009). Oxygen isotope seasonality in a temperate estuarine shell midden: a case study from CA-ALA-17 on the San Francisco Bay, California. Journal of Archaeological Science, 36, 1354–1363.CrossRefGoogle Scholar
  11. Eerkens, J. W., Byrd, B. F., Spero, H. J., & Fritschi, A. K. (2013). Stable isotope reconstructions of shellfish harvesting seasonality in an estuarine environment: implications for Late Holocene San Francisco Bay settlement patterns. Journal of Archaeological Science, 40, 2014–2024.CrossRefGoogle Scholar
  12. Faulkner, P. (2009). Focused, intense and long-term: evidence for granular ark (Anadara granosa) exploitation from late Holocene shell mounds of Blue Mud Bay, northern Australia. Journal of Archaeological Science, 36, 821–834.CrossRefGoogle Scholar
  13. Fish, P.R., Fish, S.K., DeBlasis, P., Gaspar, M.D., Thompson, V.D., Waggoner, J.C., Jr. (2013). Monumental shell mounds as persistent places in southern coastal Brazil. The archaeology and Historical Ecology of Small Scale Economies 120–140.Google Scholar
  14. García-Escárzaga, A., Moncayo, S., Gutiérrez-Zugasti, I., González-Morales, M. R., Martín-Chivelet, J., & Cáceres, J. O. (2015). Mg/Ca ratios measured by laser induced breakdown spectroscopy (LIBS): a new approach to decipher environmental conditions. Journal of Analytical Atomic Spectrometry, 30, 1913–1919.CrossRefGoogle Scholar
  15. Hausmann, N. (2015). The shell mounds of the Farasan Islands—an isotopic study of seasonality and coastal exploitation. PhD Dissertation, University of York.Google Scholar
  16. Hausmann, N., Colonese, A. C., de Lima Ponzoni, A., Hancock, Y., Meredith-Williams, M., Leng, M. J., & Bailey, G. N. (2016). Isotopic composition of Conomurex fasciatus shells as an environmental proxy for the Red Sea. Quaternary International. doi:10.1016/j.quaint.2015.08.051.Google Scholar
  17. Hayden, B. (2001). Fabulous feasts: a prolegomenon to the importance of feasting. In M. Dietler & Hayden (Eds.), Feasts: archaeological and ethnographic perspectives on food, politics, and power (pp. 23–64). Washington: Smithsonian.Google Scholar
  18. Hayden, B. (2014). The power of feasts: from prehistory to the present. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
  19. Holdaway, S., & Wandsnider, L. (Eds.). (2008). Time in archaeology: time perspectivism revisited. Salt Lake City: University of Utah Press.Google Scholar
  20. Jerardino, A. (2015). Shell density as proxy for reconstructing prehistoric aquatic resource exploitation, perspectives from southern Africa. Journal of Archaeological Science: Reports. doi:10.1016/j.jasrep.2015.06.005.Google Scholar
  21. Jew, N. P., Erlandson, J. M., Watts, J., & White, F. J. (2013). Shellfish, seasonality, and stable isotope sampling: δ 18O analysis of mussel shells from an 8,800-year-old shell midden on California’s Channel Islands. The Journal of Island and Coastal Archaeology, 8, 170–189.CrossRefGoogle Scholar
  22. Jew, N. P., Rick, T. C., Glassow, M. A., & Arnold, J. E. (2015). Bayesian 14C analysis, formation processes, and accumulation rates of the Prisoners Harbor shell midden and village complex, Santa Cruz Island, California. Journal of Archaeological Science: Reports, 3, 257–264.CrossRefGoogle Scholar
  23. Kennett, D. J., Culleton, B. J., Voorhies, B., & Southon, J. R. (2011). Bayesian analysis of high-precision AMS 14C dates from a prehistoric Mexican shellmound. Radiocarbon, 53, 245–259.CrossRefGoogle Scholar
  24. Koppel, B., Szabó, K., Moore, M. W., & Morwood, M. J. (2016). Untangling time-averaging in shell middens: defining temporal units using amino acid racemisation. Journal of Archaeological Science: Reports. doi:10.1016/j.jasrep.2015.08.040.Google Scholar
  25. Larsen, B. P., Holdaway, S. J., Fanning, P. C., Mackrell, T., & Shiner, J. I. (2016). Shape as an outcome of formation history: Terrestrial Laser Scanning of shell mounds from far north Queensland, Australia. Quaternary International. doi:10.1016/j.quaint.2015.06.066.Google Scholar
  26. Leng, M.J., Lewis, J.P. (2014). Oxygen isotopes in Molluscan shell: applications in environmental archaeology. Environmental Archaeology. 141119000730007 Google Scholar
  27. Lombardo, U., Szabo, K., Capriles, J. M., May, J.-H., Amelung, W., Hutterer, R., Lehndorff, E., Plotzki, A., & Veit, H. (2013). Early and middle holocene hunter-gatherer occupations in western Amazonia: the hidden shell middens. PloS One, 8, e72746.CrossRefGoogle Scholar
  28. Magnani, M., & Schroder, W. (2015). New approaches to modeling the volume of earthen archaeological features: a case-study from the Hopewell culture mounds. Journal of Archaeological Science, 64, 12–21.CrossRefGoogle Scholar
  29. Mannino, M. A., & Thomas, K. D. (2001). Intensive mesolithic exploitation of coastal resources? Evidence from a shell deposit on the Isle of Portland (Southern England) for the impact of human foraging on populations of intertidal rocky shore molluscs. Journal of Archaeological Science, 28, 1101–1114.CrossRefGoogle Scholar
  30. Mannino, M. A., Spiro, B. F., & Thomas, K. D. (2003). Sampling shells for seasonality: oxygen isotope analysis on shell carbonates of the inter-tidal gastropod Monodonta lineata (da Costa) from populations across its modern range and from a Mesolithic site in southern Britain. Journal of Archaeological Science, 30, 667–679.CrossRefGoogle Scholar
  31. Marquardt, W. H. (2010). Shell mounds in the southeast: middens, monuments, temple mounds, rings, or works? American Antiquity, 75, 551–570.CrossRefGoogle Scholar
  32. McNiven, I. J. (2012). Ritualized middening practices. Journal of Archaeology Method and Theory, 20(4), 552–587.CrossRefGoogle Scholar
  33. Meredith-Williams, M. G., Hausmann, N., Bailey, G. N., King, G. C. P., Alsharekh, A., Ghamdi, S. A., & Inglis, R. H. (2014a). Mapping, modelling and predicting prehistoric coastal archaeology in the southern Red Sea using new applications of digital-imaging techniques. World Archaeology, 46, 10–24.CrossRefGoogle Scholar
  34. Meredith-Williams, M. G., Hausmann, N., Inglis, R., Bailey, G. (2014b). 4200 new shell mound sites in the southern Red Sea. Human Exploitation of Aquatic Landscapes’ special issue (ed. Ricardo Fernandes and John Meadows), Internet Archaeology. http://dx. doi. org/10. 11141/ia 37.Google Scholar
  35. Morrison, M. (2014). Chronological trends in late Holocene shell mound construction across northern Australia Insights from Albatross Bay, Cape York Peninsula. Australian Archaeology 79.Google Scholar
  36. Russo, M., & Heide, G. (2001). Shell rings of the southeast US. Antiquity, 75, 491–492.CrossRefGoogle Scholar
  37. Saunders, R. (2004). Spatial variation in Orange Culture pottery. Early pottery: technology, function, style, and interaction in the lower Southeast 40–62.Google Scholar
  38. Saunders, R., Russo, M. (2011). Coastal shell middens in Florida: a view from the Archaic period 239, 38–50,Google Scholar
  39. Schwadron, M. (2010). Prehistoric landscapes of complexity: archaic and woodland period shell works, shell rings and tree islands of the Everglades, south Florida. Trend, Tradition, and Turmoil: What Happened to the Southeastern Archaic 113–147.Google Scholar
  40. Schweikhardt, P., Ingram, B. L., Lightfoot, K., & Luby, E. (2011). Geochemical methods for inferring seasonal occupation of an estuarine shellmound: a case study from San Francisco Bay. Journal of Archaeological Science, 38, 2301–2312.CrossRefGoogle Scholar
  41. Shiner, J.S., Fanning, P.C., Holdaway, S.J., Petchey, F., Beresford, C., Hoffman, E., Larsen, B. (2007). Shell mounds as the basis for understanding human-environment interaction in 2005, 2006 Google Scholar
  42. Stein, J.K. (1992). The analysis of shell middens. Deciphering a Shell Midden 1–24.Google Scholar
  43. Stein, J. K., Deo, J. N., & Phillips, L. S. (2003). Big sites—short time: accumulation rates in archaeological sites. Journal of Archaeological Science, 30, 297–316.CrossRefGoogle Scholar
  44. Thomas, K. D. (2015). Molluscs emergent, part II: themes and trends in the scientific investigation of molluscs and their shells as past human resources. Journal of Archaeological Science, 1–9.Google Scholar
  45. Thompson, V., & Andrus, C. (2011). Evaluating mobility, monumentality, and feasting at the Sapelo Island Shell Ring Complex. American Antiquity, 76, 315–344.CrossRefGoogle Scholar
  46. Twiss, K. C. (2008). Transformations in an early agricultural society: feasting in the southern Levantine Pre-Pottery Neolithic. Journal of Anthropological Archaeology, 27, 418–442.CrossRefGoogle Scholar
  47. Villagran, X. S., Balbo, A. L., Madella, M., Vila, A., & Estevez, J. (2011). Stratigraphic and spatial variability in shell middens: microfacies identification at the ethnohistoric site Tunel VII (Tierra del Fuego, Argentina). Archaeological and Anthropological Sciences, 3, 357–378.CrossRefGoogle Scholar
  48. Waselkov, G. A. (1987). Shellfish gathering and shell midden archaeology. Advances in Archaeological Method and Theory, 10, 93–210.CrossRefGoogle Scholar
  49. Williams, M.G.M. (2011). Prehistoric coastal archaeology of the Farasan Islands, Saudi Arabia. PhD Dissertation, University of York.Google Scholar

Copyright information

© Springer Science+Business Media New York 2016

Authors and Affiliations

  1. 1.Institute of Electronic Structure and Laser, Foundation for Research and Technology - Hellas (FORTH)HeraklionGreece
  2. 2.BioArCh, Department of ArchaeologyUniversity of YorkYorkUnited Kingdom
  3. 3.Department of History and ArchaeologyLa Trobe UniversityMelbourneAustralia

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