Intrasource Chemical Variability and Secondary Depositional Processes

Lessons from the American Southwest
  • M. Steven Shackley
Part of the Advances in Archaeological and Museum Science book series (AAMS, volume 3)

Abstract

For nearly 30 years, archaeological obsidian has been collected from geological and archaeological contexts, analyzed by a spate of methods, and offered to the scientific community as internally valid research. Virtually none of this work has been gathered in explicitly scientific ways such that the results are reliable and valid. In an attempt to provide a starting point for consideration, this chapter discusses the field and laboratory methods used in the ongoing Southwest and Northwestern Mexico Archaeological Obsidian Project dealing with arid environments, very old glass sources, relatively extreme secondary deposition, and a great range of chemical variability common in this geological context.

Keywords

Archaeological Context Source Group Dome Structure River Alluvium Chemical Variability 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

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References

  1. Baxter, M.J. 1994a Stepwise discriminant analysis in archaeometry: a critique. Journal of Archaeological Science 21: 659–666.CrossRefGoogle Scholar
  2. Baxter, M.J. 1994b Exploratory Multivari ate Analysis in Archaeology. Edinburgh, Edinburgh University Press.Google Scholar
  3. Bouska, V. 1993 Natural Glasses. New York, Ellis Horwood.Google Scholar
  4. Brooks, W. E., and Ratté, J. C. 1985 Geologic map of Bear Mountain Quadrangle, Grant CountyGoogle Scholar
  5. New Mexico. U.S. Geological Survey Miscellaneous Field Studies Map MF-1782. Burkham, D.E. 1972 Channel Changes of the Gila River in Safford Valley, Arizona, 1846–1970. USGSGoogle Scholar
  6. Professional Paper 655-G. U.S. Geological Survey.Google Scholar
  7. Church, T. 1995 Comment on Neutron Activation Analysis of Stone from the Chadron Formation and a Clovis Site on the Great Plains by Hoard et al. (1992). Journal of Archaeological Science 22: 1–5.CrossRefGoogle Scholar
  8. Duerden, P., Clayton, E., Bird, J.R., Ambrose, W, and Leach, E. 1987 Artefact composition and computation. In Ambrose, W.R., and Mummery, J.M.J, eds., Archaeometry: Further Australasian Studies. Canberra, Australian National University: 232–238.Google Scholar
  9. Elston, W. E. 1965 Rhyolite ash-flow plateaus, ring-dike complexes, calderas, lopoliths, and Moon craters. Annals of the New York Academy of Sciences 124: 817–842.Google Scholar
  10. Elston, W. E. 1976 Glossary of stratigraphic terms of the Mogollon-Datil volcanic province, New Mexico. New Mexico Geological Society Special Publication 5: 131–145.Google Scholar
  11. Elston, W. E. 1984 Mid-Tertiary ash flow tuff cauldrons, southwestern New Mexico. Journal of Geophysical Research 89: 8733–8750.CrossRefGoogle Scholar
  12. Ericson, J.E., and Glascock, M.D. 1992 Chemical characterization of obsidian flows and domes of the Coso volcanic field, China Lake, California. Poster presented at the 28th International Symposium on Archaeometry, Los Angeles, California.Google Scholar
  13. Glascock, M. D. 1991 Tables for Neutron Activation Analysis ( 3rd Edition ). Research Reactor Facility, University of Missouri, Columbia.Google Scholar
  14. Glascock, M. D. 1992 Characterization of archaeological ceramics at MURR by neutron activation analysis and multivariate statistics. In Neff, H. ed., Chemical Characterization of Ceramic Pastes in Archaeology. Madison, Prehistory Press: 11–26.Google Scholar
  15. Glascock, M. D. 1994 New world obsidian: recent investigations. In D.A. Scott, and P. Myers eds., Archaeometry of Pre-Columbian Sites and Artifacts, Proceedings of the 28th InternationalGoogle Scholar
  16. Symposium on Archaeometry. Getty Conservation Institute, Los Angeles: 113–134.Google Scholar
  17. Green, R.C. 1987 Obsidian results from the Lapita sites of the Reef/Santa Cruz Islands. In Ambrose, W.R., and Mummery, J.M.J, eds., Archaeometry: Further Australasian Studies. Canberra, The Australian National University: 239–249.Google Scholar
  18. Harbottle, G. 1982 Chemical characterization in archaeology. In Ericson, J. E. and Earle, T.K., eds., Contexts for Prehistoric Exchange. New York, Academic Press: 13–51Google Scholar
  19. Houser, B.B., Richter, D.H., and Shafiqullah, M. 1985 Geologic map of the Safford quadrangle, Graham County, Arizona. Miscellaneous Investigations Series Map 1–1617. U.S. Geological Survey.Google Scholar
  20. Huckleberry, G.A. 1995 Archaeological implications of Late-Holocene channel changes on the Middle Gila River, Arizona. Geoarchaeology 10: 159–182.CrossRefGoogle Scholar
  21. Hughes, R. E. 1988 The Coso Volcanic Field reexamined: implications for obsidian sourcing and hydration dating research. Geoarchaeology 3: 253–265.CrossRefGoogle Scholar
  22. Hughes, R. E. 1994 Intrasource chemical variability of artefact-quality obsidians from the Casa DiabloGoogle Scholar
  23. Area, California. Journal of Archaeological Science 21: 263–271.Google Scholar
  24. Hughes, R. E., and Smith, R.L. 1993 Archaeology, geology, and geochemistry in obsidian provenance studies. In Stein, J.K. and Linse, A.R., eds., Scale on Archaeological and Geoscientific Perspectives. Geological Society of America Special Paper 283: 79–91.Google Scholar
  25. International Association for Obsidian Studies (LAOS) 1994 Field and laboratory standards in obsidian geochemistry: SAA workshop sponsored by LAOS. International Association for Obsidian Studies Bulletin 11:1.Google Scholar
  26. Jack, R. N. 1971 The source of obsidian artifacts in northern Arizona. Plateau 43: 103–114.Google Scholar
  27. 1976.
    Prehistoric obsidian in California: geochemical aspects. In Taylor, R.E., ed., Advances in Obsidian Glass Studies: Archaeological and Geochemical Perspectives. Park Ridge, New Jersey, Noyes Press: 183–217.Google Scholar
  28. Jackson, T.L. 1989 Late prehistoric obsidian production and exchange in the North Coast Ranges, California. In Hughes, R.E., ed., Current Directions in California Obsidian Studies. Berkeley: Contributions of the University of California Archaeological Research Facility 48: 79–94.Google Scholar
  29. Johnson, R. A., and Wichern, D. W. 1982 Applied Multivariate Statistical Analysis. Englewood Cliffs, New Jersey, Prentice-Hall.Google Scholar
  30. Lavin, L., and Prothero, D.R. 1992 Prehistoric procurement of secondary sources: the case for characterization. North American Archaeologist 13: 97–113.CrossRefGoogle Scholar
  31. LeTourneau, P. D. 1994 Geologic investigations of the Antelope Wells obsidian source, southern Animas Mountains, New Mexico. Paper presented at the 59th Annual Meeting of the Society for American Archaeology, Anaheim, California.Google Scholar
  32. Macdonald, R., and Bailey, D.K. 1973 The Chemistry of the Peralkaline Oversaturated Obsidians. Geological Survey Professional Paper 440-N-1.Google Scholar
  33. Macdonald, R., Davies, G.R., Bliss, C.M., Leat, P.T., Bailey, D.K., and Smith, R.L. 1987 Geochemistry of high-silica peralkaline rhyolites, Naivasha, Kenya Rift Valley. Journal of Petrology 28: 979–1008.CrossRefGoogle Scholar
  34. Mahood, G., and Hildreth, W. 1983 Large partition coefficients for trace elements in high-silica rhyolites. Geochimica et Cosmochimica Acta 47: 11–30.CrossRefGoogle Scholar
  35. Mahood, G., and Stimac, J.A. 1990 Trace-element partitioning in pantellerites and trachytes. Geochimica et Cosmochimica Acta 54: 2257–2276.CrossRefGoogle Scholar
  36. Meltzer, D. J. 1985 On stone procurement and settlement mobility in eastern fluted point groups. North American Archaeologist 6: 1–27.CrossRefGoogle Scholar
  37. Mitchell, D. R., and Shackley, M. S. 1995 Classic period Hohokam obsidian studies in southern Arizona. Journal of Field Archaeology 22: 291–304.Google Scholar
  38. Nations, D., and Stump, E. 1981 Geology of Arizona. Dubuque, Iowa, Kendall/Hunt Publishing CompanyGoogle Scholar
  39. Newman, J.R. 1994 The effects of distance on lithic material reduction technology Journal of Field Archaeology 21: 491–501.Google Scholar
  40. Ratté, J. C. 1982 Geologic map of the Lower San Francisco Wilderness Study Area and contiguous roadless area, Greenlee County, Arizona, and Catron and Grant Counties, New Mexico. U.S. Geological Survey Miscellaneous Field Studies Map MF-1463-B.Google Scholar
  41. Ratté, J. C., and Brooks, W E. 1983 Geologic map of the Mule Creek Quadrangle, Grant County, New Mexico. U.S. Geological Survey Miscellaneous Studies Map MF-1666.Google Scholar
  42. Ratté, J. C., and Brooks, W E. 1989 Geologic map of the Wilson Mountain Quadrangle, Catron and Grant Counties, NewGoogle Scholar
  43. Mexico. U.S. Geological Survey Geologic Quadrangle Map GQ-1611.Google Scholar
  44. Ratté, J. C., and Hedlund, D.C. 1981 Geologic map of the Hells Hole Further Planning Area (RARE II), Greenlee County, Arizona and Grant County, New Mexico. U.S. Geological Survey Miscellaneous Field Studies Map MF-1344-A.Google Scholar
  45. Ratté, J. C., Marvin, R.F., and Naeser, C.W. 1984 Calderas and ash flow tuffs of the Mogollon Mountains, southwestern New Mexico. Journal of Geophysical Research 89: 8713–8732.CrossRefGoogle Scholar
  46. Renfrew, C. 1977 Alternative models for exchange and spatial distribution. In Earle, T.K., and Ericson, J.E., eds., Exchange Systems in Prehistory. New York, Academic Press: 71–90.Google Scholar
  47. Reynolds, S. J., Welty, J. W, and Spencer, J. E. 1986 Volcanic history of Arizona. Arizona Bureau of Geology and Mineral Technology Fieldnotes 16: 1–5.Google Scholar
  48. Rhodes, R. and Smith, E. 1972 Geology and tectonic setting of the Mule Creek Caldera, New Mexico, USA. Bulletin Volcanologie 36: 401–411.CrossRefGoogle Scholar
  49. Richter, D.H., Houser, B.B., and Damon, P.E. 1983 Geologic map of the Guthrie quadrangle, Graham and Greenlee Counties, Arizona. Miscellaneous Investigations Series Map 1–455, U.S. Geological Survey.Google Scholar
  50. Shackley, M. S. 1987 Comment on Tomato Springs: the identification of a jasper trade and production center in Southern California. American Antiquity 52: 616–623.CrossRefGoogle Scholar
  51. Shackley, M. S. 1988 Sources of archaeological obsidian in the Southwest: an archaeological, petrological, and geochemical study. American Antiquity 53: 752–772.CrossRefGoogle Scholar
  52. Shackley, M. S. 1990 Early hunter-gatherer procurement ranges in the Southwest: evidence from obsidian geochemistry and lithic technology. Ph.D. dissertation, Arizona State University. Ann Arbor, University Microfilms.Google Scholar
  53. Shackley, M. S. 1992 The Upper Gila River gravels as an archaeological obsidian source region: implications for models of exchange and interaction. Geoarchaeology 7: 315–326.CrossRefGoogle Scholar
  54. Shackley, M. S. 1993a Gamma rays, x-rays, stone tools and the “sourcing” myth: are we missing the point?Google Scholar
  55. Paper presented in the symposium Archaeological Science: Past Achievements/Future Directions,at the 58th Annual Meeting of the Society for American Archaeology, St. Louis.Google Scholar
  56. Shackley, M. S. 1993b (ms) Obsidian procurement and distribution in prehistoric sites in the San Simon Archaeological Project, Southeastern Arizona: an energy dispersive x-ray fluorescence (edxrf) study. Prepared for Pat Gilman, Department of Anthropology, University of Oklahoma, Norman.Google Scholar
  57. Shackley, M. S. 1994 Intersource and intrasource geochemical variability in two newly discovered archaeological obsidian sources in the Southern Great Basin: Bristol Mountains, California andGoogle Scholar
  58. Devil Peak, Nevada. Journal of California and Great Basin Anthropology 16: 118–129.Google Scholar
  59. Shackley, M. S. 1995 Sources of archaeological obsidian in the greater American Southwest: an update and quantitative analysis. American Antiquity 60: 531–551.CrossRefGoogle Scholar
  60. Shelley, P.H. 1993 A geoarchaeological approach to the analysis of secondary lithic deposits. Geoarchaeology 8: 59–72.CrossRefGoogle Scholar
  61. Skinner, C. 1983 (ms) Obsidian studies in Oregon: an introduction to obsidian and an investigation of selected methods of obsidian characterization utilizing obsidian collected at prehistoric quarry sites in Oregon. M.A. thesis, University of Oregon.Google Scholar
  62. Wilson, E. D., and Moore, R. T. 1958 Geologic map of Graham and Greenlee Counties, Arizona. Arizona Bureau of Mines, University of Arizona.Google Scholar
  63. Wyckoff, D.G. 1993 Gravel sources of knappable alibates silicified dolomite. Geoarchaeology 8: 35–58.CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media New York 1998

Authors and Affiliations

  • M. Steven Shackley
    • 1
  1. 1.Phoebe Hearst Museum of Anthropology and Department of AnthropologyUniversity of CaliforniaBerkeleyUSA

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