Hostname: page-component-78c5997874-xbtfd Total loading time: 0 Render date: 2024-11-05T14:05:24.122Z Has data issue: false hasContentIssue false
  • English
  • Français

The Hydroarchaeological Method: A Case Study at the Maya Site of Palenque

Published online by Cambridge University Press:  20 January 2017

Kirk D. French ,
Christopher J. Duffy  and
Gopal Bhatt
Kirk D. French
Affiliation:
Department of Anthropology, Pennsylvania State University, University Park, PA 16802 ([email protected])
Christopher J. Duffy
Affiliation:
Department of Civil and Environmental Engineering, Pennsylvania State University, University Park, PA 16802
Gopal Bhatt
Affiliation:
Department of Civil and Environmental Engineering, Pennsylvania State University, University Park, PA 16802
Get access Rights & Permissions [Opens in a new window]

Abstract

This research consists mainly of introducing the hydroarchaeological method, especially as related to issues of drought. The article outlines how this multidisciplinary method can provide insights into the success and failures of an archaeological site, in this case the Maya site of Palenque. We also detail convincing evidence that shows that the Maya of Palenque did not leave their city because of deficiencies of water, as some paleoclimatologists and archaeologists have asserted. The first logical step toward understanding any settlement’s water system is to use basic hydrologic methods and theory and to understand the local watershed. There is great potential for watershed-climate modeling in developing plausible scenarios of water use and supply and of the effect of extreme conditions (flood and drought), all of which cannot be fully represented by atmosphere-based climate and weather projections. The research demonstrates how the local watershed, land-use, and ecological conditions interact with regional climate changes. The archaeological implications for this noninvasive “virtual” method are many, including detecting periods of stress within a community, estimating population by developing caps based on the availability of water, and understanding settlement patterns, as well as assisting present local populations in understanding their water cycle.

El objetivo principal de esta investigación es la introducción del método hidroarqueológico, especialmente en lo relacionado a temas como la sequía. El artículo describe cómo este método multidisciplinario ayuda a entender las causas del éxito y fracaso de un sitio arqueológico, en este caso, del sitio maya de Palenque. También detallamos evidencia convincente que muestra que—a diferencia de lo que algunos paleoclimatólogos y arqueólogos han afirmado—los mayas de Palenque no abandonaron su ciudad debido a escasez de agua. El primer paso lógico para entender el sistema hidráulico de cualquier asentamiento es usar la teoría y métodos hidrológicos básicos, y conocer la cuenca hidrológica local. Existe un gran potencial para los modelos climatológicos-hidrológicos para proporcionar posibles escenarios de uso y abasto de agua, y los efectos de posibles condiciones extremas (inundación y sequía), todo lo cual no puede ser representado totalmente mediante pronósticos del tiempo y del clima que se basan en la atmósfera únicamente. Esta investigación demuestra cómo interactúan las cuencas locales, el uso de la tierra y las condiciones ecológicas, con los cambios climáticos regionales. Las implicaciones arqueológicas de este método no-invasivo “virtual” son muchas, incluyendo: la detección de periodos de estrés en el interior de una comunidad; la estimación de la población al diseñar topes de crecimiento basados en la disponibilidad de agua; la comprensión de los patrones de asentamiento; así como la asistencia a las poblaciones actuales en la localidad para el entendimiento de su ciclo de agua.

Type
Articles
Information
Latin American Antiquity , Volume 23 , Issue 1 , March 2012 , pp. 29 - 50
Copyright
Copyright © 2012 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

Abrams, Elliot M., and Rue, David J. 1988 The Causes and Consequences of Deforestation among the Prehistoric Maya. Human Ecology 16:377395.CrossRefGoogle Scholar
Andrews, George 1975 Maya Cities: Placemaking and Urbanization. University of Oklahoma Press, Norman.Google Scholar
Ashmore, Wendy, Yaeger, Jason, and Robin, Cynthia 2004 Commoner Sense: Late and Terminal Classic Social Strategies in the Xunantunich Area. In The Terminal Classic in the Maya Lowlands: Collapse, Transition, and Transformation, edited by Arthur A. Demarest, Prudence M. Rice, and Don S. Rice, pp. 302323. University of Press of Colorado, Boulder.Google Scholar
Back, William, and Lesser, Juan M. 1981 Chemical Constraints on Ground-Water Management in the Yucatán Peninsula, Mexico. Journal of Hydrology 51(1-4):119130.CrossRefGoogle Scholar
Barnhart, Edwin L. 2001 The Palenque Mapping Project: Settlement and Urbanism at an Ancient Maya City. Unpublished Ph.D. dissertation, Department of Anthropology, University of Texas, Austin.Google Scholar
Bishop, Ronald L. 1994 Pre-Columbian Pottery: Research in the Maya Region. In Archaeometry of Pre-Columbian Sites and Artifacts, edited by David A. Scott and Peter Meyers, pp. 1565. Getty Conservation Institute, Los Angeles.Google Scholar
Brenner, Mark, Hodell, David A., Curtis, Jason H., Rosenmeier, Michael F., Anselmetti, Flavio S., and Ariztegui, Daniel 2003 Paleoliminological Approaches for Inferring Past Climate Change in the Maya Region: Recent Advances and Methodological Limitations. In The Lowland Maya Area: Three Millennia at the Human–Wildland Interface, edited by Arturo Gomez-Pompa, Michael F. Allen, Scott L. Fedick, and Juan Jimenez-Osornio, pp. 4575. Food Products Press, New York.Google Scholar
Bryson, Reid A., and DeWall, Katherine M. 2007 A Paleoclimatology Workbook: High Resolution, Site-Specific, Macrophysical Climate Modeling. Mammoth Site, Hot Springs, South Dakota.Google Scholar
Bryson, Robert U., Bryson, Reid A., and Ruter, Henry 2006 A Calibrated Radiocarbon Database of Late Quaternary Volcanic Eruptions. Electronic document, http://www.electronic-earth-discuss.net/l/123/2006/eed-1-123-2006-print.pdf, accessed January 5, 2012.CrossRefGoogle Scholar
Curtis, Jason, Hodell, David A., and Brenner, Mark 1996 Climate Variability on the Yucatán Peninsula (Mexico) During the Past 3500 Years, and Implications for Maya Cultural Evolution. Quaternary Research 46:3747.CrossRefGoogle Scholar
Dahlin, Bruce H. 1983 Climate and Prehistory on the Yucátan Peninsula. Climatic Change 5(3):245263.CrossRefGoogle Scholar
Dahlin, Bruce H., Quizar, Robin, and Dahlin, Andrea 1987 Linguistic Divergence and the Collapse of Late Pre-classic Maya Civilization. American Antiquity 52(2):367382.CrossRefGoogle Scholar
Deevey, Edward S. 1978 Holocene Forests and Maya Disturbance Near Quexil Lake, Peten, Guatemala. Polish Archives of Hydrobiology 25(1/2):117129.Google Scholar
Deevey, Edward S., Rice, Don S., Rice, Prudence M., Vaughan, H. H., Brenner, Mark, and Flannery, M. S. 1979 Mayan Urbanism: Impact on a Tropical Karst Environment. Science 206:298306.CrossRefGoogle ScholarPubMed
Demarest, Arthur A., Rice, Prudence M., and Rice, Don S. (editors) 2004 The Terminal Classic in the Maya Lowlands: Collapse, Transition, and Transformation. University of Colorado Press, Boulder.Google Scholar
Demeritt, David 1991 Agriculture, Climate, and Cultural Adaptation in the Prehistoric Northeast. Archaeology of Eastern North America 19:183202.Google Scholar
Denevan, William M., and Turner, B. L. II 1985 Calculating Population and Agricultural Intensity Levels from Field Remains: A Comment on Coe's Review of “Maya Subsistence.” American Antiquity 50:166169.CrossRefGoogle Scholar
Dunning, Nicholas, Beach, Timothy, Farrell, Pat, and Luzzadder-Beach, Sheryl 1998 Prehispanic Agrosystems and Adaptive Regions in the Maya Lowlands. Culture and Agriculture 20(2/3):87101.CrossRefGoogle Scholar
Fedick, Scott L. 1996 The Managed Mosaic: Ancient Maya Agriculture and Resource Use. University of Utah Press, Salt Lake City.Google Scholar
Ferrusquia-Villafranca, Ismael 1993 Geology of Mexico: A Synopsis. In Biological Diversity of Mexico: Origins and Distribution, edited by Antonio Lot, Robert Bye, and Thennilapuram P. Ramamoorthy, pp. 3107. Oxford University Press, New York.Google Scholar
Ferziger, Joel H., and Peric, Milovan 2002 Computational Methods for Fluid Dynamics. Springer, New York.CrossRefGoogle Scholar
Flannery, Kent V. 1978 Maya Subsistence: Studies in Memory of Dennis E. Puleston. Academic Press, New York.Google Scholar
Folan, William J., Gunn, Joel, Eaton, Jack D., and Patch, Robert W. 1983 Paleoclimatological Patterning in Southern Mesoamerica. Journal of Field Archaeology 10:453468.Google Scholar
Food and Agriculture Organizations of the United Nations 2002 Maize. Electronic document, http://www.fao.org/landandwater/aglw/cropwater/maize.stm#requirements, accessed January 5, 2012.Google Scholar
Frappier, Amy, Sahagian, Dork, González, Luis A., and Carpenter, Scott J. 2002 El Niño Events Recorded by Stalagmite Carbon Isotopes. Science 298(5593):565.CrossRefGoogle ScholarPubMed
French, Kirk D. 2007 Creating Space Through Water Management at the Classic Maya Site of Palenque, Chiapas, Mexico. In Palenque: Recent Investigations at the Classic Maya Center, edited by Damien Marken, pp. 123132. AltaMira Press, Lanham, Maryland.Google Scholar
French, Kirk D. 2009 The Hydroarchaeological Approach: Understanding the Ancient Maya Impact on the Palenque Watershed. Unpublished Ph.D. dissertation, Department of Anthropology, Pennsylvania State University, University Park.Google Scholar
French, Kirk D., and Duffy, Christopher J. 2010 Prehispanic Water Pressure: A New World First. Journal of Archaeological Science 37(5):10271032.CrossRefGoogle Scholar
French, Kirk D., Stuart, David, and Morales, Alfonso 2006 Archaeological and Epigraphic Evidence for Water Management and Ritual at Palenque. In Precolumbian Water Management: Ideology, Ritual and Power, edited by Barbara Fash and Lisa Lucero, pp. 144152. University of Arizona Press, Tucson.Google Scholar
Gill, Richard B. 2000 The Great Maya Droughts: Water, Life, and Death. University of New Mexico Press, Albuquerque.Google Scholar
Gill, Richard B., Mayewski, Paul A., Nyberg, Johan, Haug, Gerald H., and Peterson, Larry C. 2007 Drought and the Maya Collapse. Ancient Mesoamerica 18:283302.CrossRefGoogle Scholar
Gray, Stephen T., Betancourt, Julio L., Jackson, Stephen T., and Eddy, Robert G. 2006 Role of Multidecadal Climate Variability in a Range Extension of Pinyon Pine. Ecology 87:11241130.CrossRefGoogle Scholar
Gunn, Joel D., and Adams, Richard E. W. 1981 Climatic-Change, Culture, and Civilization in North-America. World Archaeology 13(1):87100.CrossRefGoogle Scholar
Gunn, Joel D., and Folan, William J. 2000 Three Rivers: Subregional Variations in Earth System Impacts in the Southwestern Maya Lowlands (Candelaria, Usumacinta, and Champoton Watersheds). In The Way the Wind Blows: Climate, History, and Human Action, edited by Roderick Mcintosh, Joseph A. Tainter, and Susan Keech McIntosh, pp. 263270. Columbia University Press, New York.Google Scholar
Gunn, Joel D., Folan, William J., and Robichaux, Hubert R. 1995 A Landscape Analysis of the Candelaria Watershed in Mexico: Insights into Paleoclimates Affecting Upland Horticulture in the Southern Yucatán Peninsula Semi-Karst. Geoarchaeology 10:342.CrossRefGoogle Scholar
Hansen, Richard D., Bozarth, Steven, Jacob, John, Wahl, David, and Schreiner, Thomas 2002 Climatic and Environmental Variability in the Rise of Maya Civilization: A Preliminary Perspective from Northern Petén. Ancient Mesoamerica 13:273295.CrossRefGoogle Scholar
Harrison, Peter D., and Turner, Billie L. II 1978 Pre-Hispanic Maya Agriculture. University of New Mexico Press, Albuquerque.Google Scholar
Haug, Gerald H., Günther, Detlef, Peterson, Larry C., Sigman, Daniel M., Hughen, Konrad A., and Aeschlimann, Beat 2003 Climate and the Collapse of Maya Civilization. Science 299(5613):17311735.CrossRefGoogle ScholarPubMed
Hisdal, Hege, Tallaksen, Lena M., Clausen, Bente, Peters, Elizabeth, and Gustard, A. 2004 Hydrological Drought Characteristics. In Developments in Hydrological Drought: Processes and Estimation Methods for Streamflow and Groundwater, edited by Lena M. Tallaksen and Henny A. J. Van Lanen, pp. 139198. Developments in Water Science No. 48. Elsevier, Oxford.Google Scholar
Hodell, David A., Brenner, Mark, and Curtis, Jason H. 2007 Climate and Cultural History of the Northeastern Yucatán Peninsula, Quintana Roo, Mexico. Climatic Change 83:215240.CrossRefGoogle Scholar
Hodell, David A., Brenner, Mark, Curtis, Jason H., and Guilderson, Thomas P. 2001 Solar Forcing of Drought Frequency in the Maya Lowlands. Science 292:13671370.CrossRefGoogle ScholarPubMed
Hodell, David A., Brenner, Mark, Curtis, Jason H., Medina-Gonzalez, Roger, Can, Enrique Ildefonso-Chan, Albornaz-Pat, Alma, and Guilderson, Thomas P. 2005 Climate Change on the Yucatán Peninsula During the Little Ice Age. Quaternary Research 63:109121.CrossRefGoogle Scholar
Hodell, David A., Curtis, Jason H., and Brenner, Mark 1995 Possible Role of Climate in the Collapse of the Classic Maya Civilization. Nature 375:391394.CrossRefGoogle Scholar
Holdridge, Leslie R., Grenke, W. C., Hatheway, W. H., Liang, T., and Tosi, J. A. Jr. 1971 Forest Environments in Tropical Life Zones: A Pilot Study. Pergamon Press, Oxford.Google Scholar
Intergovernmental Panel on Climate Change 1996 Climate Change 1995: The Science of Climate Change. Contribution of Working Group I to the Second Assessment Report of the Intergovernmental Panel on Climate Change. Edited by John T. Houghton, Gylvan M. Filho, Arie Kattenberg, and Kathy Maskell. Cambridge University Press, Cambridge.Google Scholar
Jones, Peter G., and Thornton, Philip K. 2003 The Potential Impacts of Climate Change on Maize Production in Africa and Latin America in 2055. Global Environmental Change 13(1):5159.CrossRefGoogle Scholar
LeCount, Lisa J., Yaeger, Jason, Leventhal, Richard M., and Ashmore, Wendy 2002 Dating the Rise and Fall of Kunantunich, Belize. Ancient Mesoamerica 13:4163.CrossRefGoogle Scholar
Leyden, Barbara W., Brenner, Mark, and Dahlin, Bruce H. 1998 Cultural and Climatic History of Coba, a Lowland Maya City in Quintana Roo, Mexico. Quaternary Research 49:111122.CrossRefGoogle Scholar
Liendo, Rodrigo 1999 The Organization of Agricultural Production at a Maya Center. The Settlement Patterns in the Palenque Region, Chiapas, Mexico. Instituto Nacional de Antropología e Historia, Mexico City.Google Scholar
Linsley, Ray K., Kohler, Max Adam, and Paulhus, Joseph L. H. 1982 Hydrology for Engineers. 3rd ed. McGraw-Hill, New York.Google Scholar
Littman, Edwin R. 1959 Ancient Mesoamerican Mortars, Plasters, and Stuccos: Palenque, Chiapas. American Antiquity 25:264266.CrossRefGoogle Scholar
Lucero, Lisa J. 2002 The Collapse of the Classic Maya: A Case for the Role of Water Control. American Anthropologist 104:814826.CrossRefGoogle Scholar
Lucero, Lisa J. 2006 Water and Ritual: The Rise and Fall of Classic Maya Rulers. University of Texas Press, Austin.CrossRefGoogle Scholar
Lucero, Lisa J., Gunn, Joel D., and Scarborough, Vernon 2011 Climate Change and Classic Maya Water Management. Water 3:479494.CrossRefGoogle Scholar
Magana, Victor, Amador, Jorge A., and Medina, Socorro 1999 The Midsummer Drought Over Mexico and Central America. Journal of Climate 12(6): 15771588.2.0.CO;2>CrossRefGoogle Scholar
Matthews, William J., and March-Matthews, Edie 2003 Effects of Drought on Fish Across Axes of Space, Time and Ecological Complexity. Freshwater Biology 48:12321253.CrossRefGoogle Scholar
Medina-Elizalde, Martín, Burns, Stephen, Lea, David W., Asmerom, Yemane, Gunten, Lucien von, Polyak, Vicotor, Vuille, Mathias, and Karmalkar, Ambarish 2010 High Resolution Stalagmite Climate Record from the Yucatán Peninsula Spanning the Maya Terminal Classic Period. Earth and Planetary Science Letters 298:255262.CrossRefGoogle Scholar
Myers, Norman 1997 Environmental Refugees. Population Environment 19(2):167182.CrossRefGoogle Scholar
National Land Cover Database 2001 National Land Cover Database 2001, Multi-Resolution Land Characteristics Consortium. Electronic document, http://www.mrlc.gov/nlcd.php, accessed June 2009.Google Scholar
National Research Council 2004 Confronting the Nation's Water Problems: The Role of Research. National Academy Press, Washington, D.C. Google Scholar
National Research Council 2005 Network Science. National Academy Press, Washington, D.C. Google Scholar
National Research Council 2007 Colorado River Basin Water Management: Evaluating and Adjusting to Hydroclimatic Variability. National Academies Press, Washington, D.C. Google Scholar
National Research Council 2008 Integrating Multiscale Observations of U.S. Waters. National Academy Press, Washington, D.C. Google Scholar
Nencetti, A., Tassi, Franco, Vaselli, Orlando, Macías, Jose Luis, Magro, Gabriella, Capaccioni, Bruno, Minissale, Angelo, and Mora, Juan C. 2005 Chemical and Isotopic Study of Thermal Springs and Gas Discharges from Sierra de Chiapas, Mexico. Geofísica Internacional 44:3948.CrossRefGoogle Scholar
Palmer, Wayne C. 1965 Meteorological Drought. Research Paper No. 5. Office of Climatology, U.S. Weather Bureau, Washington, D.C. Google Scholar
Pohl, Mary 1985 Prehistoric Lowland Maya Environment and Subsistence Economy. Harvard University Press Peabody Museum Papers, Vol. 77. Cambridge.Google Scholar
Pohl, Mary D., Pope, Kevin O., Jones, John G., Jacob, John S., Piperno, Dolores R., deFrance, Susan, Lentz, David L., Gifford, John A., Danforth, Marie E., and Josserand, J. Kathryn 1996 Early Agriculture in the Maya Lowlands. Latin American Antiquity 7:355372.CrossRefGoogle Scholar
Qu, Yizhong, and Duffy, Christopher J. 2007 An Integrated Hydrologic Model for Multi-Process Simulation. Water Resource Research 43:118.Google Scholar
Rands, Robert L. 1974 The Ceramic Sequence at Palenque, Chiapas. In Mesoamerican Archaeology: New Approaches, edited by Norman Hammond, pp. 5175. Duckworth, London; and University of Pittsburgh Press, Pittsburgh.Google Scholar
Rands, Robert L., and Bishop, Ronald L. 1980 Resource Procurement Zones and Patterns of Ceramic Exchange in the Palenque Region, Mexico. In Models and Methods in Regional Exchange, edited by Robert Fry, pp. 1946. Society for American Archaeology Papers 1. Washington, D.C. Google Scholar
Reed, David 1998 Ancient Maya Diet at Copán. Unpublished Ph.D. dissertation, Department of Anthropology, Pennsylvania State University, University Park.Google Scholar
Ruter, Anthony, Arzt, Jennifer, Vavrus, Steven, Bryson, Reid A., and Kutzbach, John E. 2004 Climate and Environment of the Subtropical and Tropical Americas (NH) in the Mid-Holocene: Comparison of Observations with Climate Model Simulations. Quaternary Science Reviews 23:663679.CrossRefGoogle Scholar
Salas, Jose D. 1993 Analysis and Modeling of Hydrologic Time Series. In Handbook of Hydrology, edited by David R. Maidment, 19.1–19.63. McGraw-Hill, New York.Google Scholar
Sanders, William T., and Webster, David 1988 The Mesoamerican Urban Tradition. American Anthropologist 90:521546.CrossRefGoogle Scholar
Sands, Phil 2009 Refugees Because the Rains Never Came. The National, September 3.Google Scholar
Scarborough, Vernon L. 2003 The Flow of Power: Ancient Water Systems and Landscapes. School of American Research, Santa Fe.Google Scholar
Scarborough, Vernon L. 2008 Rate and Process of Societal Change in Semitropical Settings: The Ancient Maya and the Living Balinese. Quaternary International 184:2440.CrossRefGoogle Scholar
Schreiner, Thomas Paul 2002 Traditional Maya Lime Production: Environmental and Cultural Implications of a Native American Technology. Unpublished Ph.D. dissertation, Department of Architecture, University of California, Berkeley.Google Scholar
Sedlock, Richard L., Ortega-Gutierrez, Fernando, and Speed, Robert C. 1993 Technostratigraphic Terranes and Tectonic Evolution in Mexico. Special Paper 278. Geological Society of America, Boulder.Google Scholar
Siemens, Alfred H., and Puleston, Dennis E. 1972 Ridged Fields and Associated Features in Southern Campeche: New Perspectives on the Lowland Maya. American Antiquity 37:228239.CrossRefGoogle Scholar
Stahle, David W, Cook, Edward R., Diaz, Jose Villanueva, Fye, Falko K., Burnette, Dorian J., Griffin, R. Daniel, Acuna Soto, Rodolfo, Seager, Richard, and Heim, Richard R. Jr. 2009 Early 21st Century Drought in Mexico. Eos 90(11):8990.CrossRefGoogle Scholar
Stewart, Iris T., Cayan, Daniel R., and Dettinger, Michael D. 2004 Changes in Snowmelt Runoff Timing in Western North America Under a “Business as Usual” Climate Change Scenario. Climate Change 62:217232.CrossRefGoogle Scholar
Straight, Kirk D. 2007 Construction, Proportion, and Form at Temple XIX, Palenque. In Palenque: Recent Investigations at the Classic Maya Center, edited by Damien Marken, pp. 175204. AltaMira Press, Lanham, Maryland.Google Scholar
Tallaksen, Lena M., and van Lanen, Henny A. J. (editors) 2004 Hydrological Drought: Processes and Estimation Methods for Streamflow and Groundwater. Elsevier, Oxford.Google Scholar
Tedlock, Dennis (translator) 1985 Popol Vuh: The Definitive Edition of the Mayan Book of the Dawn of Life and the Glories of God and Kings. Simon and Schuster, New York.Google Scholar
Trenberth, Kevin E., and Otto-Bliesner, Bette L. 2003 Toward Integrated Reconstruction of Past Climate. Science 300:589591.CrossRefGoogle Scholar
Turner, Billie L. II, and Harrison, Peter D. 1983 Pulltrouser Swamp: Ancient Maya Habitat, Agriculture, and Settlement in Northern Belize. University of Texas Press, Austin.Google Scholar
Vaughn, B. H., Raymond, C. F., Rasmussen, L. A., Miller, D. S., Michaelson, C. A., Meier, M. F., Krimmel, R. M., Fountain, A. G., Dunlap, W. W., and Brown, C. S. 1985 Short-Term Velocity Measurements at Columbia Glacier, Alaska: August-September 1984. U.S. Geological Survey. Open File Report 29:85487.Google Scholar
Villanueva-Diaz, Jose, Stahle, David, Luckman, Brian, Cerano-Paredes, Julian, Therrell, Mathew, Cleaveland, Malcolm, and Cornejo-Oviedo, Eladio 2007 Winter-Spring Precipitation Reconstruction from Tree Rings for Northeast Mexico. Climatic Change 83:117131.Google Scholar
Webster, David 2002 The Fall of the Ancient Maya: Solving the Mystery of the Maya Collapse. Thames and Hudson, New York.Google Scholar
Webster, James W., Brook, George A., Bruce Railsback, L., Hai Cheng, R. Edwards, Lawrence, Alexander, Clark, and Reeder, Philip P. 2007 Stalagmite Evidence from Belize Indicating Significant Droughts at the Time of Precl as sic Abandonment, the Maya Hiatus, and the Classic Maya Collapse. Palaeogeography, Palaeoclimatology, Palaeoecology 250(1–4): 117.CrossRefGoogle Scholar
Westerhng, Anthony L., Hidalgo, Hugo G., Cayan, Daniel R., and Swetnam, Thomas W. 2006 Warming and Earlier Spring Increase Western US Forest Wildfire Activity. Science 313:940943.CrossRefGoogle Scholar
Whitmore, Thomas J., Brenner, Mark, Cuitis, Jason, Dahlin, Bruce H., and Leyden, Barbara 1996 Holocene Climate and Human Influences on Lakes of the Yucatan Peninsula, Mexico: An Interdisciplinary Paleolimnological Approach. The Holocene 6:273287.CrossRefGoogle Scholar
Worster, Donald 1979 Dust Bowl: The Southern Plains in the 1930's. Oxford University Press, New York.Google Scholar
Yaeger, Jason, and Hodell, David A. 2008 The Collapse of Maya Civilization: Assessing the Interaction of Culture, Climate, and Environment. In El Niño: Catastrophism and Culture Change in Ancient America, edited by Daniel H. Sandweiss and Jeffrey Quilter, pp. 187242. Dumbarton Oaks, Washington, D.C. Google Scholar
Zhang, Pingzhong, Hai Cheng, R. Edwards, Lawrence, Chen, Fahu, Wang, Yongjin, Yang, Xunlin, Liu, Jian, Tan, Ming, Wang, Xianfeng, Liu, Jinghua, An, Chunlei, Dai, Zhibo, Zhou, Jing, Zhang, Dexhong, Jia, Jihong, Jin, Liya, and Johnson, Katleen R. 2008 A Test of Climate, Sun, and Culture Relationships from an 1810- Year Chinese Cave Record. Science 322(5903):940942.CrossRefGoogle Scholar