Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-12-05T02:13:12.942Z Has data issue: false hasContentIssue false
  • English
  • Français

A Non-Destructive Method for Dating Human Remains

Published online by Cambridge University Press:  16 January 2017

Warren K. Lail ,
David Sammeth ,
Shannon Mahan  and
Jason Nevins
Warren K. Lail
Affiliation:
New Mexico Highlands University
David Sammeth
Affiliation:
New Mexico Highlands University
Shannon Mahan
Affiliation:
US Geological Survey
Jason Nevins
Affiliation:
New Mexico Highlands University
Get access Rights & Permissions [Opens in a new window]

Abstract

The skeletal remains of several Native Americans were recovered in an eroded state from a creek bank in northeastern New Mexico. Subsequently stored in a nearby museum, the remains became lost for almost 36 years. In a recent effort to repatriate the remains, it was necessary to fit them into a cultural chronology in order to determine the appropriate tribe(s) for consultation pursuant to the Native American Grave Protection and Repatriation Act (NAGPRA). Because the remains were found in an eroded context with no artifacts or funerary objects, their age was unknown. Having been asked to avoid destructive dating methods such as radiocarbon dating, the authors used Optically Stimulated Luminescence (OSL) to date the sediments embedded in the cranium. The OSL analyses yielded reliable dates between A.D. 1415 and A.D. 1495. Accordingly, we conclude that the remains were interred somewhat earlier than A.D. 1415, but no later than A.D. 1495. We believe the remains are from individuals ancestral to the Ute Mouache Band, which is now being contacted for repatriation efforts. Not only do our methods contribute to the immediate repatriation efforts, they provide archaeologists with a versatile, non-destructive, numerical dating method that can be used in many burial contexts.

Los restos óseos de varios nativos americanos fueron recuperados al encontrarles en estado de erosión a la orilla de un arroyo en el noreste de Nuevo México. Al ser subsecuentemente almacenados en un museo cercano, los restos se perdieron entre las colecciones por casi 36 años. Recientemente, ante la necesidad de repatriarlos a la tribu de nativos americanos correspondiente, ha sido necesario ubicarles en una cronología cultural, de conformidad con el Acta de Protección y Repatriación de Tumbas de los Nativos Norteamericanos (NAGPRA), para consultar con la tribu o tribus apropiadas. Dado que los restos fueron encontrados en un contexto erosionado, sin artefactos u objetos funerarios, se desconoce su antigüedad. Al haberse pedido que no se utilizaran métodos de datación destructivos, como radiocarbono, los autores utilizaron luminiscencia ópticamente estimulada (OSL) para fechar los sedimentos que se encontraban al interior del cráneo. Los análisis de OSL proveyeron fechas confiables entre 1415 y 1495 d.C. Consecuentemente, concluimos que los restos fueron enterrados poco antes de 1415 d.C., mas no después de 1495 d.C. Nosotros creemos que los restos son ancestros de los miembros de la banda Mouache Ute, a quienes se les ha contactado como parte de las acciones de repatriación. No solo nuestros métodos contribuyen a estos esfuerzos inmediatos de repatriación, éstos proveen a los arqueólogos con un método de datación versátil y no destructivo que puede utilizarse en distintos contextos mortuorios.

Type
Research Article
Information
Advances in Archaeological Practice , Volume 1 , Issue 2 , November 2013 , pp. 91 - 103
Copyright
Copyright © Society for American Archaeology 2013

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

References Cited

25 U.S.C. 3001 et seq. 1990 Native American Graves and Repatriation Act.Google Scholar
43 CFR 10 2010 Native American Graves Protection and Repatriation Act Regulations— Disposition of Culturally Unidentifiable Human Remains; Final Rule.Google Scholar
Aitken, M. J. 1985 Thermoluminescence Dating. Academic Press, London.Google Scholar
Aitken, M. J. 1998 An Introduction to Optical Dating. Oxford, Oxford University Press.Google Scholar
Aitken, M. J., and Alldred, J.C. 1972 The Assessment of Error Limits in Thermoluminescent Dating. Archaeometry 14(2):257267.Google Scholar
Arnold, L., Bailey, R., and Tucker, G. 2007 Statistical Treatment of Fluvial Dose Distributions from Southern Colorado Arroyo Deposits. Quaternary Geochronology 2:162167.Google Scholar
Bailey, R., Smith, B. and Rhodes, E. 1997 Partial Bleaching and the Decay Form Characteristics of Quartz OSL. Radiation Measurements 27:123136.Google Scholar
Berg, Gregory E. 2008 Biological Affinity and Sex Determination Using Morphometric and Anthroposcopic Variables from the Human Mandible. Ph.D. dissertation, Department of Anthropology, University of Tennessee.Google Scholar
Bishop, P., Sanderson, D., Hansom, J., and Chaimanee, N. 2005 Age-Dating of Tsunami Deposits: Lessons from the 26 December 2004 Tsunami in Thailand. The Geographical Journal 171(4):379384.Google Scholar
Buikstra, J. E., and Ubelaker, D. H. 1994 Standards for Data Collection from Human Skeletal Remains. Fayetteville, AR. Arkansas Archaeological Survey Research Series 44.Google Scholar
Burns, Karen R. 2013 Forensic Anthropology Training Manual. 3rd ed. Pearson, Boston.Google Scholar
Duller, G.A.T. 2007 Assessing the Error on Equivalent Dose Estimates Derived from Single Aliquot Regenerative Dose Measurements. Ancient TL 25:1524.Google Scholar
Duller, G.A.T. 2008a Luminescence Dating: Guidelines on Using Luminescence Dating in Archaeology. English Heritage, Swindon.Google Scholar
Duller, G.A.T. 2008b Single-grain Optical Dating of Quaternary Sediments: Why Aliquot Size Matters in Luminescence Dating. Boreas 37:589612.Google Scholar
Feathers, James K., Holliday, Vance, and Meltzer, David. 2006 OSL Dating of Southern High Plains Archaeological Sites. Journal of Archaeological Science 33:16511665.CrossRefGoogle Scholar
France, D. 1998 Observational and Metric Analysis of Sex in the Skeleton. In Forensic Osteology: Advances in the Identification of Human Remains, edited by Reichs, K. J.. 2nd ed. Thomas, Charles C., Springfield, Illinois.Google Scholar
Galbraith, R. 2005 Statistics for Fission Track Analysis. Chapman and Hall/CRC, Boca Raton.Google Scholar
Galbraith, R., Roberts, R., Laslett, G., Yoshide, A., and Olley, J.. 1999 Optical Dating of Single and Multiple Grains of Quartz from Jinmium Rock Shelter, Northern Australia, Pt. I: Experimental Design and Statistical Models. Archaeometry 41:339364.Google Scholar
Highman, T.F.G., Jacobi, R.M., and Bronk Ramsey, C. 2006 AMS Radiocarbon Dating of Ancient Bone Using Ultrafiltration. Radiocarbon 48(2):179195.Google Scholar
Huckleberry, Gary, Stein, Julie and Goldberg, Paul. 2003 Determining the Provenience of Kennewick Man Skeletal Remains through Sedimentological Analyses. Journal of Archaeological Science 30:651665.CrossRefGoogle Scholar
Jacobs, Z., Roberts, R., Galbraith, R., Deacon, H., Grün, R., Mackay, A., Mitchell, P., Vogelsang, R., and Wadley, L.. 2008 Ages for the Middle Stone Age of Southern Africa: Implications for Human Behavior and Dispersal. Science 322:733.Google Scholar
Keleher, William A. 1964 The Maxwell Land Grant. University of New Mexico Press, Albuquerque.Google Scholar
Krogman, M. 1962 The Human Skeleton in Forensic Medicine. Charles C. Thomas, Springfield, Illinois.Google Scholar
Lail, Warren K. 2008 Behavioral Regions Analysis of the Poñil Canyon, Colfax County, New Mexico. Ph.D. dissertation, Department of Anthropology, University of Oklahoma, Norman.Google Scholar
Larsen, Clark S. 1995 Biological Changes in Human Populations with Agriculture. Annual Review of Anthropology 24:185213.Google Scholar
Lepper, K., Gorz, K., Fisher, T., and Lowell, T.. 2011 Age Determinations for Glacial Lake Agassiz Shorelines West of Fargo, North Dakota, USA. Canadian Journal of Earth Sciences 48:11991207.CrossRefGoogle Scholar
Lieberman, Leonard, Stevenson, Blaine W., and Reynolds, Larry T. 1989 Race and Anthropology: A Core Concept without Consensus. Anthropology and Education Quarterly 20(2):6773 CrossRefGoogle Scholar
Mann, R., Symes, S., and Bass, W. 1987 Maxillary Suture Obliteration: Aging the Human Skeleton Based on Intact of Fragmentary Maxilla. Journal of Forensic Sciences 32:148157.Google Scholar
Meindl, Richard S. and Owen Lovejoy, C. 1985 Ectocranial Suture Closure: A Revised method for the Determination of Skeletal Age at Death Based on the Lateral-Anterior Sutures. American Journal of Physical Anthropology 68:2945.Google Scholar
Murray, A., and Wintle, A. 2000 Luminescence Dating of Quartz Using An Imroved Single-Aliquot Regenerative-Dose Protocol. Radiation Measurements. 32(1):5773.Google Scholar
Murray, A., and Wintle, A. 2003 The Single Aliquot Regenerative Dose Protocol: Potential for Improvements in Reliability. Radiation Measurements 37:377381.CrossRefGoogle Scholar
Murray, A., and Olley, J. 2002 Precision and Accuracy in the Optically Stimulated Luminescence Dating of Sedimentary Quartz: A Status Review. Geochronometria 21:116.Google Scholar
Murray, A., Thomsen, K., Masuda, N., Buylaert, J., and Jain, M. 2012 Identifying Well-bleached Quartz Using the Different Bleaching Rates of Quartz and Feldspar Luminescence Signals. Radiation Measurements 47:688695.Google Scholar
Ousley, Stephen 2013 ADBOU® 2.1.037. Software, available at http://math.mercyhurst.edu/∼sousley/Software.Google Scholar
Ousley, S., Jantz, R., and Fried, D. 2009 Understanding Race and Human Variation: Why Forensic Anthropologists Are Good at Identifying Race. American Journal of Physical Anthropology 139(1):6876.Google Scholar
Ousley, S.D., and Jantz, R.L. 2005 FORDISC 3.0: Personal Computer Forensic Discriminant Functions. Department of Anthropology, University of Tennessee, Knoxville, TN.Google Scholar
Prescott, J. and Hutton, J. 1988 Cosmic Ray and Gamma Ray Dosimetry for TL and ESR. Radiation Measurements 14:223230.Google Scholar
Prescott, J. and Hutton, J. 1994 Cosmic Ray Contributions to Dose Rates for Luminescence and ESR Dating: Large Depths and Long-term Time Variations. Radiation Measurements 23:497500.Google Scholar
Prideaux, G., Gully, G., Couzens, A., Ayliffe, L., Jankowski, N., Jacobs, Z., Roberts, R., Hellstrom, J., Gagan, M. and Hatcher, L. 2010 Timing and Dynamics of Late Pleistocene Mammal Extinctions in Southwestern Australia. PNAS 107(51):2215722162.Google Scholar
Ramsthaler, F., Kreutz, K., and Verhoff, M.A. 2007 Accuracy of Metric Sex Analysis of Skeletal Remains Using Fordisc ® Based on a Recent Skull Collection. International Journal of Legal Medicine 121:477482.Google Scholar
Rhodes, E. 2011 Optically Stimulated Luminescence Dating of Sediments over the Past 200,000 Years. Annual Review of Earth and Planetary Sciences 39:461488.CrossRefGoogle Scholar
Rink, W.J., Dunbar, J.S., Tschinkel, W.R., Kwapich, S., Repp, A., Stanton, W., and Thulman, D. K. 2013 Subterranean Transport and Deposition of Quartz by Ants in Sandy Sites Relevant to Age Overestimation in Optical Luminescence Dating. Journal of Archaeological Science 40(4):22172226.Google Scholar
Rittenour, T. 2008 Luminescence Dating of Fluvial Deposits: Applications to Geomorphic, Paleoseismic and Archeological Research. Boreas 37:613635.Google Scholar
Roberts, R., Flannery, T., Ayliffe, L., Yoshida, H., Olley, j., Prideaux, G., Laslett, G., Baynes, A., Smith, M., Jones, R., and Smith, B. 2001 New Ages for the Last Australian Megafauna: Continent-wide Extinction about 46,000 Years Ago. Science 292:18881892.Google Scholar
Robinson, G., Wanek, A., Hays, W., and McCallum, M. 1964 Philmont Country: The Rocks and Landscape of a Famous New Mexico Ranch. Geological Survey Professional Paper 505, United States Government Printing Office, Washington, D.C. Google Scholar
Rodnight, H. 2008 How Many Equivalent Dose Values Are Needed to Obtain a Reproducible Distribution? Ancient TL 26(1):39.Google Scholar
Sauer, Norman J. 1992 Forensic Anthropology and the Concept of Race: If Races Don't Exist, Why Are Forensic Anthropologists So Good at Identifying Them? Social Science & Medicine 34(2):107111.Google Scholar
Sauer, Norman J. and Wankmiller, Jane C. 2009 The Assessment of Ancestry and the Concept of Race in Handbook of Forensic Archaeology and Anthropology . World Archaeological Congress, edited by Nicholas, George and Hollowell, Julie, pp. 187200. Left Coast Press, Walnut Creek, CA.Google Scholar
Schoeneberger, P.J., Wysocki, DA., Benham, E.C., and Soil Survey Staff. 2012 Field Book for Describing and Sampling Soils, Version 3.0, Natural Resources Conservation Service, National Soil Survey Center, Lincoln, Nebraska.Google Scholar
Scientific Working Group for Forensic Anthropology (SWGANTH) 2013 Ancestry Assessment. Electronic document, http://swganth.startlogic.com/Ancestry%20Assessment%20Rev0.pdf, accessed November 11, 2013.Google Scholar
Scott, G. Richard, and Turner, Christy G. II 1988 Dental Anthropology. Annual Review of Anthropology 17:99126.Google Scholar
Simmons, Virginia M. 2000 The Ute Indians of Utah, Colorado, and New Mexico. University Press of Colorado, Boulder.Google Scholar
Smithsonian Institution 2011 Osteoware® 2.4. Software, available at http://osteoware.si.edu. Google Scholar
Snow, Clyde C. 1982 Forensic Anthropology. Annual Review of Anthropology 11:97131.Google Scholar
Suma, G.N., Rao, Balaji, Annigeri, Rajeshwari, RAo, Dayashankara, and Goel, Sumit 2011 Radiographic Correlation of Dental and Skeletal Age: Third Molar, an Age Indicator. Journal of Forensic Dental Sciences 3(1):1418.Google Scholar
Tuan, Yi-Fu, Cyril E., Evard, Widdison, Jerold G., and Bennett, Iven 1973 The Climate of New Mexico. Revised edition. New Mexico State Planning Office, Santa Fe.Google Scholar
Tuteja, Monica, Bahirwani, Shraddha, and Balaji, P. 2012 An Evaluation of Third Molar Eruption for Assessment of Chronological Age: A Panoramic Study. Journal of Forensic Dental Sciences 4(1):1318.Google Scholar
Jakob, Wallinga 2002 Optically stimulated luminescence dating of fluvial deposits: a review. Boreas 31(4):303322.Google Scholar
Walker, P. L. 2008 Sexing Skulls Using Discriminant Function Analysis of Visually Assessed Traits. American Journal of Physical Anthropology 136:3950.Google Scholar
Waters, M. S. Forman, Jennings, T., Nordt, L., Direse, S., Feinberg, J., Keene, J., Halligan, J., Lindquist, A., Pierson, J., Hallmark, C., Collings, M., and Wiederhold, J. 2011 The Buttermilk Creek Complex and the Origins of Clovis at the Debra L. Friendkin Site, Texas. Science 331(6024):15991603.Google Scholar
Waters, M., Forman, S., Stafford, T., and Foss, J. 2009 Geoarchaeological Investigations at the Topper and Big Pine Tree Sites, Allendale County, South Carolina. Journal of Archaeological Science 36:13001311.Google Scholar
White, Tim D. and Folkens, Pieter A. 2005 The Human Bone Manual. Academic Press, New York.Google Scholar
Wintle, A., and Murray, S. 2006 A Review of Quartz Optically Stimulated Luminescence Characteristics and Their Relevance in Single-aliquot Regeneration Dating Protocols. Radiation Measurements 41:369391.Google Scholar