Hostname: page-component-78c5997874-8bhkd Total loading time: 0 Render date: 2024-11-15T21:30:42.178Z Has data issue: false hasContentIssue false
  • English
  • Français

Archaeofaunal Accumulation, Fragmented Forests, and Anthropogenic Landscape Mosaics in the Tropical Lowlands of Prehispanic Ecuador

Published online by Cambridge University Press:  20 January 2017

Peter W. Stahl
Peter W. Stahl*
Affiliation:
Department of Anthropology, Binghamton University, State University of New York, Binghamton, NY 13902-6000
Get access Rights & Permissions [Opens in a new window]

Abstract

This study examines archaeofaunal materials contained within a large bell-shaped prehistoric pit from the site of Pechichal (M3B4-011) in northern Manabí Province of lowland western Ecuador. This feature provides a high resolution archaeological context for understanding assemblage accumulation and deposition, and provides important data for inferring local environmental conditions. The archaeofaunal assemblage can be divided into two distinct groups based upon the vertical representation of its skeletal remains throughout the pit. One group, characterized by variable skeletal representation and vertical concentration, likely includes both culturally disposed and naturally entrapped taxa. The other group, characterized by a few isolated fragments, low skeletal completeness, and dispersion in vertical profile, is likely dominated by culturally disposed taxa. When the natural histories of the pit faunas are considered along with their distinct numerical representation, the entire pit assemblage makes ecological sense. The data suggest that the pit was located at the edge of a modified forest fragment.

Resumen

Resumen

En este estudio se analizan los materiales arqueofaunisticos encontrados en una formación tronco-cónica grande (Elemento 5) del sitio de Pechichal (M3B4-011) al norte de la provincia de Manabí, en las tierras bajas del occidente de Ecuador. Este elemento representa un contexto arqueológico de alta resolución para comprender la acumulación y depósito del conjunto zooarqueológico y proporciona datos importantes para inferir las condiciones ambientales locales. El conjunto de arqueofauna puede dividirse en dos grupos distintos con base en la representación vertical de los restos de esqueletos en el pozo. Un grupo, que se caracteriza por la representación variable de materiales zooarqueológicos y su concentración vertical, posiblemente incluye tanto restos que se depositaron por procesos culturales como de animales que quedaron atrapados ahí. El otro grupo, que se caracteriza por pocos fragmentos aislados, esqueletos relativamente incompletos y su dispersión en el perfil vertical, probablemente representa restos arqueofaunísticos que se depositaron intencionalmente en el basurero. Al considerar las historias naturales de los restos de animales del basurero al igual que su representación numérica diferencial, la colección cobra sentido ecológico. Los datos sugieren que el pozo se localizaba en la orilla de un sector boscoso modificado.

Type
Articles
Information
Latin American Antiquity , Volume 11 , Issue 3 , September 2000 , pp. 241 - 257
Copyright
Copyright © 2000 by the Society for American Archaeology

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

Albuja, L. V. 1991 Lista de Vertebrados del Ecuador. Mamíferos. Politécnica 16:163207.Google Scholar
Alho, C. J. R. 1982 Brazilian Rodents: Their Habitats and Habits. In Mammalian Biology in South America, edited by M.A. Mares and H. H. Genoways, pp. 143166. Pymatuning Laboratory of Ecology, Special Publication Series, Vol. 6. University of Pittsburgh, Pittsburgh..Google Scholar
Armitage, P. L., and West, B. W. 1985 Faunal Evidence from a Late Medieval Garden Well of the Greyfriars, London. Transactions of the London and Middlesex Archaeological Society 36:107136.Google Scholar
Balée, W. 1989 The Culture of Amazonian Forests. Advances in Economic Botany 7:121.Google Scholar
Bennett, J. L. 1999 Thermal Alteration of Bone. Journal of Archaeological Science 26:18.Google Scholar
Bierregaard, R. O. Jr. 1990 Species Composition and Trophic Organization of the Understory Bird Community in a Central Amazonian Terra Firme Forest. In Four Neotropical Rainforests, edited by A. H. Gentry, pp. 217236. Yale University Press, New Haven.Google Scholar
Bierregaard, R. O. Jr., and Lovejoy, T. E. 1989 Effects of Forest Fragmentation on Amazonian Understory Bird Communities. Acta Amazonica 19:215241.Google Scholar
Bierregaard, R. O. Jr., Lovejoy, T. E., Kapos, V., Augusto dos Santos, A., and Hutchings, R. W. 1992 The Biological Dynamics of Rainforest Fragments. Bioscience 42:859866.Google Scholar
Bierregaard, R. O. Jr., and Stouffer, P. C. 1997 Understory Birds and Dynamic Habitat Mosaics in Amazonian Rainforests. In Tropical Forest Remnants. Ecology, Management and Conservation of Fragmented Communities, edited by W. F. Laurance and R. O. Bierregaard, Jr., pp. 13155. University of Chicago Press, Chicago.Google Scholar
Bodmer, R. E., and Sowls, L. K. 1993 The Collared Peccary (Tayassu tajacu) . In Pigs, Peccaries, and Hippos, edited by W. L. R. Oliver, pp. 713. International Union for Conservation of Nature and Natural Resources, Gland, Switzerland.Google Scholar
Brown, K. S. Jr., and Hutchings, R. W. 1997 Disturbance, Fragmentation, and the Dynamics of Diversity in Amazonian Forest Butterflies. In Tropical Forest Remnants. Ecology, Management and Conservation of Fragmented Communities, edited by W. F. Laurance and R. O. Bierregaard, Jr., pp. 91110. University of Chicago Press, Chicago.Google Scholar
Cañadas Cruz, L. 1983 El Mapa Bioclimático y Ecológico del Ecuador. Banco Central del Ecuador, Quito.Google Scholar
Chomko, S. A., and Gilbert, B. M. 1991 Bone Refuse and Insect Remains: Their Potential for Temporal Resolution of the Archaeological Record. American Antiquity 56:680686.Google Scholar
Dale, V., Pearson, S. M., Offerman, H. L., and O’Neill, R. V. 1994 Relating Patterns of Land-Use Change to Faunal Biodiversity in the Central Amazon. Conservation Biology 8:10271036.Google Scholar
Didham, R. K. 1997 The Influence of Edge Effects and Forest Fragmentation on Leaf Litter Invertebrates in Central Amazonia. In Tropical Forest Remnants. Ecology, Management, and Conservation of Fragmented Communities, edited by W. F. Laurance and R. O. Bierregaard Jr., pp. 5570. University of Chicago Press, Chicago.Google Scholar
Didham, R. K., and Stork, N. E. 1998 Rise of the Supertramp Beetles. Natural History 107(6):3839.Google Scholar
Eisenberg, J. F. 1983 Behavioral Adaptations of Higher Vertebrates to Tropical Forests. In Tropical Rainforest Ecosystems, Structure and Function, edited by F. B. Golley, pp. 267278. Elsevier Scientific Publishing, Amsterdam.Google Scholar
Eisenberg, J. F. 1989 Mammals of the Neotropics. Vol.1: The Northern Neotropics. Univeisity of Chicago Press, Chicago.Google Scholar
Eisenberg, J. F., O’Connell, M. A., and August, P. V. 1979 Density, Productivity, and Distribution of Mammals in Two Venezuelan Habitats. In Vertebrate Ecology in the Northern Neotropics, edited by J. F. Eisenberg, pp. 187207. Smithsonian Institution, Washington, D.C.Google Scholar
Emmons, L. H. 1982 Ecology of Proechimys in Southeastern Peru. Tropical Ecology 23:280290.Google Scholar
Emmons, L. H. 1984 Geographic Variation in Densities and Diversities of Non-flying Mammals in Amazonia. Biotropica 16:210222.Google Scholar
Emmons, L. H., and Feer, F. 1990 Neotropical Rainforest Mammals. A Field Guide. University of Chicago Press, Chicago.Google Scholar
Fleming, T. H. 1970 Notes on the Rodent Faunas of Two Panamanian Forests. Journal of Mammalogy 51:473490.CrossRefGoogle Scholar
Hershkovitz, P. 1960 Mammals of Northern Colombia, Preliminary Report No. 8: Arboreal Rice Rats, a Systematic Revision of the Subgenus Oecomys, Genus Oryzomys . Proceedings of the United States National Museum 110:513568.Google Scholar
Hershkovitz, P. 1962 Evolution of Neotropical Cricetine Rodents (Muridae) with Special Reference to the Phyllotine Group. Fieldiana, Zoology 46:1524.Google Scholar
Hilty, S. L., and Brown, W. L. 1986 A Guide to the Birds of Colombia. Princeton University Press, Princeton.Google Scholar
Isaacson, J. S. 1994 Volcanic Sediments in Archaeological Contexts from Western Ecuador. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultural Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 131140. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Kent, S. 1999 The Archaeological Visibility of Storage: Delineating Storage from Trash Areas. American Antiquity 64:7994.CrossRefGoogle Scholar
Laurance, W. F. 1998 Fragments of the Forest. Natural History 107(6):3438.Google Scholar
Laurance, W. F., Bierregaard, R. O. Jr., Gascon, C., Didham, R. K., Smith, A. P., Lynam, A. J., Viana, V. M., Lovejoy, T. E., Sieving, K. E., Sites, J. W. Jr., Andersen, M., Tocher, M. D., Kramer, E. A., Restrepo, C., and Moritz, C. 1997 Tropical Forest Fragmentation: Synthesis of a Diverse and Dynamic Discipline. In Tropical Forest Remnants. Ecology, Management, and Conservation of Fragmented Communities, edited by W. F. Laurance and R. O. Bierregaard Jr., pp. 502514. University of Chicago Press, Chicago.Google Scholar
Linares, O. F. 1976 “Garden Hunting” in the American Tropics. Human Ecology 4:331349.Google Scholar
Lovejoy, T. E., Birregaard, R. O. Jr., Rylands, A. B., Malcolm, J. R., Quintelas, Q. E., Harper, L. H., Brown, K. S. Jr., Powell, A. H., Powell, G. V. N., Schubart, H. O. R., and Hays, M. B. 1986 Edge and Other Effects of Isolation on Amazon Forest Fragments. In Conservation Biology. The Science of Scarcity and Diversity, edited by M. E. Soulé, pp. 257285. Sinauer Associates, Sunderland, Massachusetts.Google Scholar
Lovejoy, T. E., Rankin, J. M., Bierregaard, R. O. Jr., Brown, K. S. Jr., Emmons, L. H., and Vander Voort, E. 1984 Ecosystem Decay of Amazonian Forest Remnants. In Extinctions, edited by M. H. Nitecki, pp. 295325. University of Chicago Press, Chicago.Google Scholar
Malcolm, J. R. 1994 Edge Effects in Central Amazonian Forest Fragments. Ecology 75:24382445.Google Scholar
Malcolm, J. R. 1995 Forest Structure and the Abundance and Diversity of Neotropical Small Mammals. In Forest Canopies, edited by M. D. Lowman and N. M. Nadkarni, pp. 179197. Academic Press, San Diego.Google Scholar
Malcolm, J. R. 1997a Biomass and Diversity of Small Mammals in Amazonian Forest Fragments. In Tropical Forest Remnants: Ecology, Management, and Conservation of Fragmented Communities, edited by W. F. Laurance and R. O. Bierregaard Jr., pp. 207221. University of Chicago Press, Chicago.Google Scholar
Malcolm, J. R. 1997b Insect Biomass in Amazonian Forest Fragments. In Canopy Arthropods, edited by N. E. Stork, J. Adis, and R. K. Didham, pp. 510533. Chapman and Hall, London.Google Scholar
Malcolm, J. R. 1998a High Roads to Oblivion. Natural History 107(6):4649.Google Scholar
Malcolm, J. R. 1998b A Model of Conductive Heat Flow in Forest Edges and Fragmented Landscapes. Climatic Change 39:487502.Google Scholar
March, I. J. 1993 The White-Lipped Peccary (Tayassu pecari) . In Pigs, Peccaries, and Hippos, edited by W. L. R. Oliver, pp. 1322. International Union for Conservation of Nature and Natural Resources, Gland, Switzerland.Google Scholar
Murcia, C. 1995 Edge Effects in Fragmented Forests: Implications for Conservation. Trends in Ecology and Evolution 10:5862.Google Scholar
Musser, G. G., and Williams, M. M. 1985 Systematic Studies of Oryzomyine Rodents (Muridae): Definitions of Oryzomys villosus and Oryzomys talamancae . American Museum Novitates 2810:122.Google Scholar
Pearman, P. B. 1997 Correlates of Amphibian Diversity in an Altered Landscape of Amazonian Ecuador. Conservation Biology 11:12111225.Google Scholar
Pearsall, D. M. 1994 Ethnobiological Field Research. In Regional Archaeology in Northern Manabi, Ecuador, Volume I. Environment, Cultural Chronology, and Prehistroic Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 145148. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Pearsall, D. M. 1995 “Doing” Paleoethnobotany in the Tropical Lowlands: Adaptation and Innovation in Methodology. In Archaeology in the Lowland American Tropics. Current Analytical Methods and Recent Applications, edited by P. W. Stahl, pp. 113129. Cambridge University Press, Cambridge.Google Scholar
Pearsall, D. M. 1996 Reconstructing Subsistence in the Lowland Tropics. A Case Study from the Jama River Valley, Manabi, Ecuador. In Case Studies in Environmental Archaeology, edited by E. J. Reitz, L. A. Newsom, and S. J. Scudder, pp. 233254. Plenum Press, New York.Google Scholar
Pearsall, D. M., and Stahl, P. W. 1996 Multidisciplinary Perspectives on Environmental and Subsistence Change in the Jama River Valley, Manabí, Ecuador. Paper presented at the 61 st Annual Meeting of the Society for American Archaeology, New Orleans.Google Scholar
Posey, D. A., Frechione, J., Eddins, J., and Francelino da Silva, L. 1984 Ethnoecology as Applied Anthropology in Amazonian Development. Human Organization 43:95107.CrossRefGoogle Scholar
Ramsey, C. B. 1995 Radiocarbon Calibration and Analysis of Stratigraphy: The OxCal Program. Radiocarbon 37:425430.CrossRefGoogle Scholar
Ramsey, C. B. 2000 OxCal Program v3.4. Radiocarbon Accelerator Unit, University of Oxford, Oxford.Google Scholar
Rand, A. S., and Myers, C. W. 1990 The Herpetofauna of Barro Colorado Island, Panama: An Ecological Summary. In Four Neotropical Rainforests, edited by A. H. Gentry, pp. 386409. Yale University Press, New Haven.Google Scholar
Reed, R. 1997 Forest Dwellers, Forest Protectors. Indigenous Models for International Development. Allyn and Bacon, Boston.Google Scholar
Reichel-Dolmatoff, G. 1996 The Forest Within: The World-View of the Tukano Amazonian Indians. Themis Books, Devon, England.Google Scholar
Reitz, E. J. 1994 The Wells of Spanish Florida: Using Taphonomy to Identify Site History. Journal of Ethnobiology 14:141160.Google Scholar
Robinson, S. K., and Terborgh, J. 1990 Bird Communities of the Cocha Cashu Biological Station in Amazonian Peru. In Four Neotropical Rainforests, edited by A. H. Gentry, pp. 199216. Yale University Press, New Haven.Google Scholar
Schwarzkopf, L., and Rylands, A. B. 1989 Primate Species Richness in Relation to Habitat Structure in Amazonian Rainforest Fragments. Biological Conservation 48:112.Google Scholar
Semken, H. A. Jr., and Falk, C. R. 1991 Micromammal Taphonomy of Three Late Prehistoric Plains Village Tradition Refuse Pits, Walworth County, South Dakota. In Beamers, Bobwhites, and Blue-Points: Tributes to the Career of Paul W. Parmalee, edited by J. R. Purdue, W. E. Klippel and B. W Styles, pp. 111124. Scientific Papers 23. Illinois State Museum, Springfield.Google Scholar
Stahl, P. W. 1992 Encountering Paradise Lost: The Archaeological Recovery of Ancient Biodiversity in the Lowlands of Western Ecuador. Paper presented at the 91 st Annual Meeting of the American Anthropological Association, San Francisco.Google Scholar
Stahl, P. W. 1994a Interpreting Ancient Mammalian Diversity from the Archaeofaunal Record in the Forested Lowlands of Western Ecuador. Paper presented at the 13th Annual Northeast Conference on Andean Archaeology and Ethnohistory, Ithaca.Google Scholar
Stahl, P. W. 1994b Qualitative Assessment of Archaeofaunal Taxa from the Jama Valley. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultural Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 185199. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Stahl, P. W. 1995 Differential Preservation Histories Affecting the Mammalian Zooarchaeological Record from the Forested Neotropical Lowlands. In Archaeology in the Lowland American Tropics. Current Analytical Methods and Recent Applications, edited by P. W. Stahl, pp. 154180. Cambridge University Press, Cambridge.Google Scholar
Stahl, P. W. 1996 The Recovery and Interpretation of Microvertebrate Bone Assemblages from Archaeological Contexts. Journal of Archaeological Method and Theory 3:3175.Google Scholar
Stahl, P. W. 1999 Tales from the Pit: Archaeofaunal Accumulation and Interpretation in the Tropical Lowlands of Ecuador. Paper presented at the 64th Annual Meeting of the Society for American Archaeology, Chicago.Google Scholar
Stahl, P. W., and Pearsall, D. M. 2000 Archaeobiology, Field Ecology, and Prehistoric Forest Fragmentation in the Jama Valley, Ecuador. Paper presented at the 65th Annual Meeting of the Society for American Archaeology, Philadelphia.Google Scholar
Stouffer, P. C., and Bierregaard, R. O. Jr. 1993 Spatial and Temporal Abundance Patterns of Ruddy Quail-Doves (Geotrygon montana) near Manaus, Brazil. Condor 95:896903.Google Scholar
Stouffer, P. C., and Bierregaard, R. O. Jr. 1995 Use of Amazonian Forest Fragments by Understory Insectivorous Birds. Ecology 76:24292445.Google Scholar
Suárez, E. J., Stallings, J., and Súarez, L. 1995 Small-Mammal Hunting by Two Ethnic Groups in North-western Ecuador. Oryx 29:3542.Google Scholar
Tirira, D. 1999 Mamíferos del Ecuador. Museo de Zoología, Centro de Biodiversidad y Ambiente, Pontifica Universidad Católica del Ecuador, Publicación Especial 2, Quito.Google Scholar
Tocher, M., Gascon, C., and Zimmerman, B. L. 1997 Fragmentation Effects on a Central Amazonian Frog Community: A Ten-year Study. In Tropical Forest Remnants. Ecology, Management, and Conservation of Fragmented Communities, edited by W. F. Laurance and R. O. Bierregaard Jr., pp. 124137. University of Chicago Press, Chicago.Google Scholar
Veintimilla, C. I. 1998 Analysis of Past Vegetation in the Jama River Valley, Manabí Province, Ecuador. Unpublished M.A. Thesis, Department of Anthropology, University of Missouri, Columbia.Google Scholar
Voss, R. S. 1992 A Revision of the South American Species of Sigmodon (Mammalia: Muridae) with Notes on Their Natural History and Biogeography. American Museum Novitates 3050:156.Google Scholar
Whyte, T. R. 1988 An Experimental Study of Small Animal Remains in Archaeological Pit Features. Unpublished Ph.D. dissertation, Department of Anthropology, University of Tennessee, Knoxville.Google Scholar
Whyte, T. R. 1991 Small-Animal Remains in Archaeological Pit Features. In Beamers, Bobwhites, and Blue- Points: Tributes to the Career of Paul W. Parmalee, edited by J. R. Purdue, W. E. Klippel and B. W. Styles, pp. 163176. Scientific Papers 23. Illinois State Museum, Springfield.Google Scholar
Wilson, D. E., Ascorra, C. F., and Solari T., S. 1996 Bats as Indicators of Habitat Disturbance. In Manu: The Biodiversity of Southeastern Peru, edited by D. E. Wilson and A. Sandoval, pp. 613625. Smithsonian Institution, Washington D.C.Google Scholar
Zeidler, J. A. 1982 Pot Hunting and Vandalism: An Ecuadorian Example. In Rescue Archeology. Papers from the First New World Conference on Rescue Archeology, edited by R. L. Wilson and G. Loyola, pp. 4958. The Preservation Press, Washington D.C.Google Scholar
Zeidler, J. A. 1994a Archaeological Testing in the Middle Jama Valley. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultural Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 7198. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Zeidler, J. A. 1994b Archaeological Testing in the Lower Jama Valley. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultural Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 99109. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Zeidler, J. A., Buck, C. E., and Linton, C. D. 1998 Integration of Archaeological Phase Information and Radiocarbon Results from the Jama River valley, Ecuador: ABayesian Approach. Larin American Antiquity 9:160179.Google Scholar
Zeidler, J. A., and Kennedy, R. C. 1994 Environmental Setting. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultural Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 1341. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Zeidler, J. A., and Pearsall, D. M. 1994 The Jama Valley Archaeological/Paleoethnobotanical Project: An Introduction. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultured Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 112. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Zeidler, J. A., Stahl, P., and Sutliff, M. J. 1998 Shamanistic Elements in a Terminal Valdivia Burial, Northern Manabí, Ecuador: Implications for Mortuary Symbolism and Social Ranking. In Recent Advances in the Archaeology of the Northern Andes: In Memory of Gerardo Reichel-Dclmatoff, edited by A. Oyuelo-Caycedo and J.S. Raymond, pp. 101112. Institute of Archaeology Monograph 39. University of California, Los Angeles.Google Scholar
Zeidler, J. A., and Sutliff, M. J. 1994 Definition of Ceramic Complexes and Cultural Occupation in the Jama Valley. In Regional Archaeology in Northern Manabí, Ecuador, Volume 1. Environment, Cultural Chronology, and Prehistoric Subsistence in the Jama River Valley, edited by J. A. Zeidler and D. M. Pearsall, pp. 111130. Memoirs in Latin American Archaeology No. 8. University of Pittsburgh, Pittsburgh.Google Scholar
Zimmerman, B. L., and Rodrigues, M. T. 1990 Frogs, Snakes, and Lizards of the INPA-WWF Reserves Near Manaus, Brazil. In Four Neotropical Rainforests, edited by A. H. Gentry, pp. 426454. Yale University Press, New Haven.Google Scholar