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Nine - Ceramic Use by Middle and Late Woodland Foragers of the Maritime Provinces

Published online by Cambridge University Press:  19 November 2018

Peter Jordan
Affiliation:
Rijksuniversiteit Groningen, The Netherlands
Kevin Gibbs
Affiliation:
University of California, Berkeley
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Ceramics in Circumpolar Prehistory
Technology, Lifeways and Cuisine
, pp. 168 - 192
Publisher: Cambridge University Press
Print publication year: 2019

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References

Allain, G. (1984). Research on Clay and Other Minerals in New Brunswick Appropriate to the Fabrication of Pottery. Ottawa: National Museums of Canada, Museums Assistance Programmes.Google Scholar
Andersen, S. and Malmros, C. (1984). “Madskorpe” på Ertebøllekar fra Tybrind Vig [with English summary entitled “Food crust” in Ertebølle vessels from Tybrind Vig, by U. S. Jørgensen]. Aarboger for Nordisk Oldkyndighed of Historie (1984), 78–95.Google Scholar
Arnason, T., Hebda, R. and Johns, T. (1981). Use of plants for food and medicine by native peoples of eastern Canada. Canadian Journal of Botany 59: 21892325.CrossRefGoogle Scholar
Arnold, D. (1985) Ceramic Theory and Cultural Process. New York: Cambridge University Press.Google Scholar
Binford, L. (1979). Organization and formation processes: looking at curated technologies. Journal of Anthropological Archaeology 35(3): 255273.Google Scholar
Bock, P. (1978). Micmac, in Trigger, B. (ed.) Handbook of North American Indians, Volume 15, Northeast, 1st edn, 109122. Washington, DC: Smithsonian Institution.Google Scholar
Bourque, B. and Krueger, W. (1994). Dietary reconstruction from human bone isotopes from five coastal New England populations, in Sobolik, K. (ed.) Paleonutrition: The Diet and Health of Prehistoric Americans, 1st edn, 195209. Carbondale: Southern Illinois University.Google Scholar
Braun, D. (1980). Experimental interpretation of ceramic vessel use on the basis of rim and neck formal attributes, in Fiero, D., Munson, R., McClain, M., Wilson, F and Vier, A. (eds.) The Navajo Project, Archaeological Investigations, 1st edn, 171231. Flagstaff: Museum of Northern Arizona, Research Paper 11.Google Scholar
Bush, P. and Zubrow, E. (1986). The art and science of eating. Science and Archaeology 28: 3843.Google Scholar
Cackette, M., O’Auria, J. and Snow, B. (1987). Examining earthenware vessel function by elemental phosphorous content. Current Anthropology 28(1): 121127.Google Scholar
Clancy, J. (1961). Chemical analysis of residue from Indian Hill ceramic pot. Massachusetts Archaeological Society, Bulletin 22(3/4): 4446.Google Scholar
Colonese, A., Farrell, T. Lucquin, A. Firth, D. Charlton, S. Robson, H. Alexander, M. and Craig, O. (2015). Archaeological bone lipids as palaodietary markers. Rapid Communications in Mass Spectrometry 29: 611618.Google Scholar
Condamin, J., Formenti, F., Metais, O., Michel, M. and Bond, P. (1976). The application of gas chromatography to the tracing of oil in ancient amphorae. Archaeometry 18(2): 195201.CrossRefGoogle Scholar
Correa-Ascencio, M. and Evershed, R. (2014). High throughput screening of organic residues in archaeological potsherds using direct acidified methanol extraction. Analytical Methods 6: 13301340.Google Scholar
Cramp, L. and Evershed, R. (2014). Reconstructing aquatic resource exploitation in human prehistory using lipid biomarkers and stable isotopes, in Turekian, K. and Holland, H. (eds.) Treatise on Geochemistry, Volume 14: Archaeology and Anthropology, 2nd edn, 319339. New York: Elsevier.Google Scholar
Deal, M. (1990). Exploratory analyses of food residues from prehistoric pottery and other artifacts from Eastern Canada. SAS (Society for Archaeological Sciences) Bulletin 13(1): 612.Google Scholar
Deal, M. (2008). Paleoethnobotanical research in the Maritime Provinces. North Atlantic Archaeology 1: 123.Google Scholar
Deal, M. (2017). The role of the direct historical approach in North American ethnoarchaeology: a northern perspective. Ethnoarchaeology 9(1): 3052.Google Scholar
Deal, M. and Hagstrum, M. (1995). Ceramic reuse behavior among the Maya and Wanka: implications for archaeology, in Skibo, J., Walker, W. and Neilsen, A. (eds.) Expanding Archaeology, 1st edn, 111125. Salt Lake City: University of Utah Press.Google Scholar
Deal, M., Morton, J. and Foulkes, E. (1991). The role of ceramics among the prehistoric hunter-gatherers of the Maine-Maritimes region: a view from the New Brunswick interior, in Deal, M. and Blair, S. (eds.) Prehistoric Archaeology of the Maritime Provinces: Past and Present Research, 1st edn, 188211. Fredericton: Council of Maritime Premiers, Report on Archaeology 8.Google Scholar
Deal, M. and Silk, P. (1988). Absorption residues and vessel function: a case study from the Maine-Maritimes region, in Kolb, C. and Lackey, L. (eds.) A Pot for All Reasons: Ceramic Ecology Revisited, 1st edn, 105125. Philadelphia: Laboratory of Anthropology, Temple University.Google Scholar
Denys, N. (1908). Description & Natural History of the Coasts of North America (Acadia) (1672). Ganong, W. (ed.) Toronto: Publications of the Champlain Society 2.Google Scholar
Dunnell, R. and Hunt, T. (1990). Elemental composition and inference of ceramic vessel function. Current Anthropology 31(3): 330336.Google Scholar
Eerkens, J. (2007). Organic residue analysis and the decomposition of fatty acids in ancient potsherds, in Barnard, H. and Eerkens, J. (eds.) Theory and Practice of Archaeological Residue Analysis, 1st edn, 9098. Oxford: BAR International Series 1650.Google Scholar
Erickson, V. (1978). Maliseet-Passamaquoddy, in Trigger, B. (ed.) Handbook of North American Indians, Volume 15, Northeast, 1st edn, 123136. Washington, DC: Smithsonian Institution.Google Scholar
Evershed, R. (1992). Chemical composition of bog body adipocere. Archaeometry 34: 253265.Google Scholar
Evershed, R. (1993). Biomolecular archaeology and lipids. World Archaeology 25(1): 7493.CrossRefGoogle ScholarPubMed
Evershed, R., Charters, P., Goad, L., Blinkhorn, P. and Denham, V. (1992). Lipid residue as an indicator of vessel use. Abstract from the EuroTAG 92, Theoretical Archaeology Group Conference, University of Southampton. La Tinaja 5(4): 23.Google Scholar
Evershed, R., Copley, P., Dickson, L. and Hansel, R. (2008). Experimental evidence for the processing of marine animal products and other commodities containing polyunsaturated fatty acids in pottery vessels. Archaeometry 50(1): 101113.CrossRefGoogle Scholar
Evershed, R., Heron, C. and Goad, L. (1990). Analysis of organic residues of archaeological origin by high-temperature gas chromatography-mass spectrometry. Analyst 115: 13391342.CrossRefGoogle Scholar
Farrell, T., Jordan, P., Taché, K., Lucquin, A., Gibbs, K., Jorge, A., Britton, K., Craig, O. E. and Knecht, R. (2014). Specialized processing of aquatic resources in prehistoric Alaskan pottery? A lipid-residue analysis of ceramic sherds from the Thule-Period site of Nunalleq, Alaska. Arctic Anthropology 51: 86100.Google Scholar
Frederickson, C. (1988). Gas chromatography and prehistoric tool use residues: a preliminary study. New Zealand Archaeological Association Newsletter 31(1): 2834.Google Scholar
Griffiths, D. (1978). Use-marks on historic ceramics: a preliminary study. Historical Archaeology 12: 6881.Google Scholar
Hall, G., Tarka, S., Hurst, W., Stuart, D. and Adams, R. (1990). Cacao residues in ancient Maya vessels from Rio Azul, Guatemala. American Antiquity 55(1): 138143.Google Scholar
Hally, D. (1983). Use alteration of pottery surfaces: an important source of evidence for the identification of vessel function. North American Archaeologist 4(1): 326.Google Scholar
Hally, D. (1986). The identification of vessel function: a case study from Northwest Georgia. American Antiquity 51: 267295.Google Scholar
Hansel, F., Copley, M., Madureiraa, L. and Evershed, R. (2004). Thermally produced ω-(o-alkylphenyl)alkanoic acids provide evidence for the processing of marine products in archaeological pottery vessels. Tetrahedron Letters 45: 29993002.Google Scholar
Harris, A. (2013a). Analysis of sediment associated with a ceramic vessel recovered at the End of Dyke site (BfDd-24), Gaspereau Lake, Nova Scotia. Unpublished report, Paleoethnobotany Laboratory, Department of Archaeology, Memorial University, St. John’s.Google Scholar
Harris, A. (2013b). Analysis of a second sediment associated with a ceramic vessel recovered at the End of Dyke site (BfDd-24), Gaspereau Lake, Nova Scotia. Unpublished report, Paleoethnobotany Laboratory, Department of Archaeology, Memorial University, St. John’s.Google Scholar
Harris, A., Deal, M. and Grimes, V. (2015). Mi’kmaq diet in the early historic period: new radiocarbon dates and human stable isotope data from Prince Edward Island. Paper presented at the 1st UPEI Multidisciplinary Graduate Conference, Charlottetown.Google Scholar
Hart, J., Brumbach, H. and Lusteck, R. (2007). Extending the phytolith evidence for early maize (Zea mays ssp. mays) and squash (Cucurbita sp.) in central New York. American Antiquity 72: 563583.Google Scholar
Hartery, L. (2006). A microscopic approach to Paleoeskimo plant use, in Ramsden, P. and Rankin, L. (eds.) From the Arctic to Avalon: Papers in Honour of Jim Tuck, 1st edn, 7178. London, BAR International Series 1507.Google Scholar
Hartery, L. (2010). Dorset Paleoeskimo Warm Season Adaptations in Newfoundland and Labrador. PhD dissertation, Department of Archaeology, University of Calgary, Calgary.Google Scholar
Hastorf, C. and DeNiro, M. (1985). Reconstruction of prehistoric plant production and cooking practices by a new isotopic method. Nature 315: 489491.CrossRefGoogle Scholar
Heron, C. and Evershed, R. (1993). The analysis of organic residues and the study of pottery use, in Schiffer, M. (ed.) Archaeological Method and Theory, Volume 5, 1st edn, 247284. Tucson: University of Arizona Press.Google Scholar
Heron, C., Evershed, R. and Goad, L. (1991). Effects of migration of soil lipids on organic residues associated with buried potsherds. Journal of Archaeological Science 18(6): 641675.Google Scholar
Hill, H. and Evans, J. (1989). Crops of the Pacific: new evidence from the chemical analysis of organic residues in pottery, in Harris, D. and Hillman, G. (eds.) Foraging and Farming: The Evolution of Plant Exploitation, 1st edn, 418425. London: Unwin Hyman.Google Scholar
Ikawa-Smith, F. (1976). On ceramic technology in East Asia. Current Anthropology 17(3): 513515.Google Scholar
Kingery, W. (1981). Plausible inference from ceramic artifacts. Journal of Field Archaeology 8(4): 457467.Google Scholar
Kobayashi, M. (1989). Use-wear analysis of Kalinga cooking pots. Paper presented at the 54th Annual Meeting of the Society for American Archaeology, Atlanta.Google Scholar
Kristmanson, H. (1992). The ceramic sequence for southwestern Nova Scotia: a refinement of the Petersen/Sanger model. MA thesis, Department of Anthropology, Memorial University, St. John’s.Google Scholar
Kristmanson, H. and Deal, M. (1993). The identification and interpretation of finishing marks on prehistoric Nova Scotian ceramics. Canadian Journal of Archaeology 17: 7484.Google Scholar
Le Clercq, C. (1910). New Relation of Gaspesia, with the Customs and Religion of the Gaspesian Indians. (1691). Ganong, W., tr., (ed.) Toronto: Publications of the Champlain Society 5.Google Scholar
Leonard, K. (1996). Mi’kmaq culture during the Late Woodland and Early Historic period. Ph.D. dissertation, Department of Anthropology, University of Toronto, Toronto.Google Scholar
Lescarbot, M. (1914). History of New France, Vols. I-III. 254. Toronto: Publications of the Champlain Society 1, 7 and 11.Google Scholar
Linton, R. (1944). North American cooking pots. American Antiquity 9: 369380.CrossRefGoogle Scholar
Loy, T. (1994). Methods in the analysis of starch grains on prehistoric stone tools, in Hather, J. (ed.) Tropical Archaeology, 1st edn, 86114. London: Routledge.Google Scholar
Lu, H., Yang, X., Ye, M., Liu, K., Xia, Z., Ren, X., Cai, L., Wu, N. and Liu, T. (2005). Millet noodles in Late Neolithic China. Nature 437(13): 967968.Google Scholar
Lucas, A. and Harris, J. (1962). Ancient Egyptian Materials and Industries, 1st edn, London: Edward Arnold.Google Scholar
Maillard, A. (1758). An Account of the Customs and Manners of the Micmakis and Maricheets Savage Nations, Now Dependent on the Government of Cape-Breton, 1st edn, London: S. Hooper and A. Morley.Google Scholar
Mant, A. (1957). Adipocere – A review. Journal of Forensic Medicine 4(1): 1835.Google Scholar
Malainey, M. (2007). Fatty acid analysis of archaeological residues: procedures and possibilities, in Barnard, H. and Eerkens, J. (eds.) Theory and Practice of Archaeological Residue Analysis, 1st edn, 7789. Oxford: BAR International Series 1650.Google Scholar
Mills, B. (1985). “North American cooking pots” reconsidered: some behavioral correlates of variation in cooking pot morphology. Paper presented at the 50th Annual Meeting of the Society for American Archaeology, Denver.Google Scholar
Mills, B. (1989). Integrating functional analysis of vessels and sherds through models of ceramic assemblage formation. World Archaeology 21(1): 133147.Google Scholar
Morton, J. (1989). An investigation of the use of stable isotopic analysis of encrustations on prehistoric ceramics: palaeodietary possibilities. M.Sc. thesis, Department of Geology, McMaster University, Hamilton.Google Scholar
Morton, J. and Schwarcz, H. (2004). Palaeodietary implications from stable isotopic analysis of residues on prehistoric Ontario ceramics. Journal of Archaeological Science 31: 503517.Google Scholar
Nash, R., Stewart, J. and Deal, M. (1991). Melanson: a central place in southwestern Nova Scotia, in Deal, M. and Blair, S. (eds.) Prehistoric Archaeology in the Maritime Provinces: Past and present Research, 1st edn, 213220. Fredericton: Reports in Archaeology 8. Council of Maritime Premiers.Google Scholar
Nelson, B. (1985). Reconstruction of ceramic vessels and their systemic contexts, in Nelson, B. (ed.) Decoding Prehistoric Ceramics, 1st edn, 310309. Carbondale: Southern Illinois University Press.Google Scholar
Owen, J., Forfa, D. and Greenough, J. (2014). Geochemical and mineralogical constraints on the provenance of L’sitkuk Bear River pottery from the Annapolis Basin, Nova Scotia. Canadian Journal of Archaeology 38(1): 76105.Google Scholar
Passi, S., Rothschild-Boros, M., Fasella, P., Nazzaro-Porro, M. and Whitehouse, D. (1981). An application of high-performance liquid chromatography to analysis of lipids in archaeological samples. Journal of Lipid Research 22: 778784.Google Scholar
Patrick, M., Koning, A. and Smith, A. (1985). Gas liquid chromatographic analysis of fatty acids in food residues from ceramics found in the Southwestern Cape, South Africa. Archaeometry 27(2): 231236.CrossRefGoogle Scholar
Pearsall, D. (1989). Palaeoethnobotany: A Handbook of Procedures. San Diego: Academic Press.Google Scholar
Petersen, J., and Sanger, D. (1991). An aboriginal ceramic sequence for Maine and the Maritime Provinces, in Deal, M. and Blair, S. (eds.) Prehistory of the Maritime Provinces: Past and Present Research, 1st edn, 113170. Fredericton: Council of Maritime Premiers, Reports in Archaeology 8.Google Scholar
Pike, K. (2013). Bearing identity: a biocultural analysis of human remains from Old Mission Point, New Brunswick. MA thesis, Department of Archaeology, Memorial University, St. John’s.Google Scholar
Piperno, D. and Holst, I. (1998). The presence of starch grains on prehistoric tools from the humid neotropics: indications of early tuber use and agriculture in Panama. Journal of Archaeological Science 25(8): 765776.Google Scholar
Prasad, V., Stromberg, C., Alimohammadian, H. and Sahni, A. (2005). Dinosaur coprolites and the early evolution of grasses and grazers. Science 310: 11771180.CrossRefGoogle ScholarPubMed
Reber, E. and Hart, J. (2008). Visible clues: the analysis of visible residues from New York State with gas chromatography/mass spectrometry, in Hart, J. (ed.) Current Northeast Paleoethnobotany II, 1st edn, 129130. Albany: New York State Museum Bulletin 512.Google Scholar
Reichert, E. (1913). The Differentiation and Specificity of Starches in Relation to Genera, Species, etc.: Stereochemistry Applied to Protoplasmic Processes and Products, and as a Strictly Scientific Basis for the Classification of Plants and Animals, 1st edn, Washington, DC: Carnegie Institute of Washington.Google Scholar
Rottländer, R. (1990). Lipid analysis in the identification of vessel contents, in Biers, W. and McGovern, P. (eds.) Organic Contents of Ancient Vessels: Materials Analysis and Archaeological Investigation. 3740. Philadelphia: MASCA Research Papers in Science and Archaeology 7, University of Pennsylvania.Google Scholar
Rottlander, R. and Schlichtherle, H. (1978). Food identification of samples from archaeological sites. Archaeo-Physika 10: 260267.Google Scholar
Rottlander, R. and Schlichtherle, H. (1983). Analyse friihgeschichtlicher Gefabinhalte (Analysis of contents of prehistoric vessels). Naturwissenschaften 70: 3338.Google Scholar
Rovner, I. (1971). Potential of opal phytoliths for use in palaeoecological reconstruction. Quaternary Research I. 343–359.Google Scholar
Rye, O. (1981). Pottery Technology: Principles and Reconstruction. Taraxacum, Washington: Manuals on Archaeology 4.Google Scholar
Sanders, M. (2014). End of Dyke site mitigation 2012: final report. Unpublished report submitted to Nova Scotia Power Incorporated and the Special Places Program of the Nova Scotia Department of Communities, Culture and Heritage. CRM Group, Halifax.Google Scholar
Schiffer, M. (1987). Formation Processes and the Archaeological Record, 1st edn, 276278. Albuquerque: University of New Mexico Press.Google Scholar
Schiffer, M. and Skibo, J. (1987). Theory and experiment in the study of technological change. Current Anthropology 28(5): 595622.Google Scholar
Shepard, A. (1965). Ceramics for the Archaeologist, 1st edn, Washington: Carnegie Institution of Washington, Publication 609.Google Scholar
Shott, M. (1986). Technological organization and settlement mobility: an ethnographic examination. Journal of Anthropological Research 42(1): 1551.Google Scholar
Silk, P. and Tan, S. (1988). Analysis of residual fatty acids in soil, ceramic and seal tissues. Chemical and Biotechnical Services, Research and Productivity Council of New Brunswick, Report #C/88/063, Fredericton.Google Scholar
Skibo, J. (1992). Pottery Function: A Use-Alteration Perspective, 1st edn, New York: Plenum.Google Scholar
Skibo, J. (2013). Understanding Pottery Function (Manuals in Archaeological Method, Theory and Technique. 174. New York: Springer.Google Scholar
Skibo, J. and Deal, M. (1995). Pottery function and organic residues: an appraisal, in Yeung, C. and Wai-ling, B. (eds.) Conference Papers on Archaeology in Southeast Asia, 1st edn, 319330. Hong Kong: University Museum and Art Gallery, University of Hong Kong.Google Scholar
Skibo, J. and Schiffer, M. (1989). Provisional theory of ceramic abrasion. American Anthropologist 91: 101115.Google Scholar
Smith, M. (1985). Toward an economic interpretation of ceramics: relating vessel size and shape to use, in Nelson, B. (ed.) Decoding Prehistoric Ceramics, 1st edn, 254309. Carbondale: Southern Illinois University Press.Google Scholar
Smith, M. (1988). Function from whole vessel shape: a method and an application to Anasazi Black Mesa, Arizona. American Antiquity 90: 912922.Google Scholar
Speiss, A. (1981). Progress in prehistoric technology: advances in cooking practices. Bulletin of the Maine Archaeological Society 21(1): 813.Google Scholar
Stapelfeldt, K. (2010a). A form and function study of precontact pottery from Atlantic Canada. MA thesis, Department of Archaeology, Memorial University, St. John’s.Google Scholar
Stapelfeldt, K. (2010b). Pottery form and function in Nova Scotia. Nova Scotia Museum, Newsletter 2010 (1): 2127.Google Scholar
Steponaitis, V. (1984). Technological studies of prehistoric pottery from Alabama: physical properties and vessel function, in van der Leeuw, S. and Prichard, A. (eds.) The Many Dimensions of Pottery, 1st edn, 81122. Amsterdam: University of Amsterdam.Google Scholar
Suttie, B. (2014). Internal research activity report: stable isotope signatures derived from encrustations on low fired pre-Contact ceramic and steatite vessel fragments from New Brunswick. Ms. on file, Archaeological Services, Fredericton.Google Scholar
Taché, K. and Craig, O. (2015). Cooperative harvesting of aquatic resources and the beginning of pottery production in northeastern North America. Antiquity 89: 177190.Google Scholar
Taché, K., White, D. and Seelen, S. (2008). Potential functions of Vinette 1 pottery: complementary use of archaeological and pyrolysis GC/MC data. Archaeology of Eastern North America 36: 6390.Google Scholar
Trueman, S. (1966). The Ordeal of John Gyles: Being an Account of His Odd Adventures, Strange Deliverances etc. as a Slave of the Maliseets, 1st edn, 3840. Toronto: McCelland and Stuart.Google Scholar
Von Stokar, W. (1938). Prehistoric organic remains. Antiquity 12: 8286.Google Scholar
Zarrillo, S. and Kooyman, B. (2006) Evidence for berry and maize processing on the Canadian Plains from starch grain analysis. American Antiquity 71(3): 473499.Google Scholar
Zarrillo, S., Pearsall, D., Raymond, J., Tisdale, M. and Quon, D. (2008). Directly dated starch residues document early formative maize (Zea mays L.) in tropical Ecuador. Proceedings of the National Academy of Sciences 105 (13): 50065011Google Scholar

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