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An 18 ka to present pollen- and phytolith-based vegetation reconstruction from Hall's Cave, south-central Texas, USA

Published online by Cambridge University Press:  07 May 2019

Carlos E. Cordova Open the ORCID record for Carlos E. Cordova [Opens in a new window]  and
William C. Johnson
Carlos E. Cordova*
Affiliation:
Department of Geography, Oklahoma State University, Stillwater, Oklahoma 74078, USA Laboratory of Archaeometry, Kazan Federal University, Kazan 420008, Tatarstan, Russia
William C. Johnson
Affiliation:
Department of Geography and Atmospheric Science, University of Kansas, 1475 Jayhawk Blvd., Lawrence, Kansas 66045, USA
*
*Corresponding author e-mail address: carlos.cordova@okstate.edu (C.E. Cordova).
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Abstract

Pollen, spores, phytoliths, and microscopic charcoal from a sedimentary column in Hall's Cave, south-central Texas, provide information for local and regional vegetation change during the last deglaciation and the Holocene in the context of broader regional and global climatic changes. The combination of paleoenvironmental proxy data from the cave indicates that between about 18,000 and 16,500 cal yr BP the cave area was dominated by an open plant community consisting of herbaceous vegetation, dominated by C3 grasses, and scattered trees, primarily Quercus and Pinus species. After about 16,500 cal yr BP, the arboreal component fluctuated, attaining a peak between 14,000 and 13,000 cal yr BP with relatively equal proportions of C3 and C4 grasses, including a sizable proportion of Panicoideae grasses. The Younger Dryas is marked by a conspicuous decrease in arboreal pollen with an apparent increase of C4 grasses toward its termination. Early Holocene recovery of arboreal vegetation is followed by a drying trend marked by the increasing dominance of C4 drought-tolerant Chloridoideae grasses. Increasing human use of the cave in middle to late Holocene times creates noise in the climatic significance of pollen, phytolith, and other proxies, a factor to consider when interpreting paleoenvironmental proxies in other cave sedimentary records.

Keywords

Fossil pollenPhytolithsSporesCave sedimentsTerminal PleistoceneHolocene
Type
Research Article
Information
Quaternary Research , Volume 92 , Issue 2 , September 2019 , pp. 497 - 518
Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2019 

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References

REFERENCES

Aharon, P., 2003. Meltwater flooding events in the Gulf of Mexico revisited: implications for rapid climate changes during the last deglaciation. Paleoceanography 18, 1079.Google Scholar
Albert, L.E., 1981. Ferndale Bog and Natural Lake: Five Thousand Years of Environmental Change in Southeastern Oklahoma. Studies in Oklahoma's Past 1. Oklahoma Archaeological Survey, Norman, OK.Google Scholar
Armstrong, W.E., Harmel, D.E., Anderegg, M.J., Traweek, M.S., 1991. Vegetation of the Kerr Wildlife Management Area and Its Preference by White-Tailed Deer: A Checklist (No. 30) . Texas Parks and Wildlife Department, Fisheries and Wildlife Division, Wildlife Section , Austin, TX.Google Scholar
Banner, J.L., Guilfoyle, A., James, E.W., Stern, L.A., Musgrove, M., 2007. Seasonal variations in modern speleothem calcite growth in central Texas, USA. Journal of Sedimentary Research 77, 615622.Google Scholar
Barnes, V.E., Rose, P.R., 1981. Geologic Atlas of Texas (Llano Sheet) . Bureau of Economic Geology, Austin, TX.Google Scholar
Blaauw, M., Christen, J.A., 2011. Flexible paleoclimate age–depth models using an autoregressive gamma process. Bayesian Analysis 6, 457474.Google Scholar
Blum, M.D., Toomey, R.S. III, Valastro, S. Jr., 1994. Fluvial response to Late Quaternary climatic and environmental change, Edwards Plateau, Texas. Palaeogeography, Palaeoclimatology, Palaeoecology 108, 121.Google Scholar
Boulter, C.M., Bateman, M.D., Frederick, C.D., 2010. Understanding geomorphic responses to environmental change: a 19 000-year case study from semi-arid central Texas, USA. Journal of Quaternary Science 25, 889902.Google Scholar
Bousman, C.B., 1998. Paleoenvironmental change in central Texas: the palynological evidence. Plains Anthropology 43, 201219.Google Scholar
Bryant, V.M. Jr., 1977. A 16,000 year pollen record of vegetational change in central Texas. Palynology 1:143156.Google Scholar
Bryant, V.M. Jr., 1978. Late Quaternary pollen records from the east-central periphery of the Chihuahuan Desert. In: Wauer, R.H., Riskind, D.H. (Eds.), Transactions of the Symposium on the Biological Resources of the Chihuahuan Desert Region, United States and Mexico (Alpine, Texas, October 1974) . National Park Service Transactions and Proceedings Series, No. 3. U.S. Department of the Interior, National Park Service , Washington, DC, pp. 322.Google Scholar
Bryant, V.M. Jr., Holloway, R.G., 1985. A Late-Quaternary paleoenvironmental record of Texas: an overview of pollen evidence. In: Bryant, V.M. Jr., Holloway, R.G. (Eds.), Pollen Records of the Late Quaternary North American Sediments. American Association of Stratigraphic Palynologists, Dallas, TX, pp. 3970.Google Scholar
Cooke, M.J., Stern, L.A., Banner, J.L., Mack, L.E., Stafford, T.W., Toomey, R.S. III, 2003. Precise timing and rate of massive late Quaternary soil denudation. Geology 31, 853856.Google Scholar
Cordova, C.E., Johnson, W.C., Mandel, R.D., Palmer, M.W., 2011. Late Quaternary environmental change inferred from phytoliths and other soil-related proxies: case studies from the central and southern Great Plains, USA. Catena 85, 87108.Google Scholar
Cordova, C.E., Scott, L., Chase, B.M. and Chevalier, M., 2017. Late Pleistocene-Holocene vegetation and climate change in the Middle Kalahari, Lake Ngami, Botswana. Quaternary Science Reviews 171, 199215.Google Scholar
Ellwood, B.B., Gose, W.A., 2006. Heinrich H1 and 8200 yr B.P. climate events recorded in Hall's Cave, Texas. Geology 34, 753756.Google Scholar
Farjon, A., 2010. A Handbook of the World's Conifers. Koninklijke Brill, Leiden, the Netherlands.Google Scholar
Farjon, A., 2013. Pinus remota. The IUCN Red List of Threatened Species 2013: e.T42409A2978032 (accessed April 1, 2019). https://www.iucnredlist.org/species/42409/2978032Google Scholar
Feng, W., Hardt, B.F., Banner, J.L., Meyer, K.J., James, E.W., Musgrove, M., Edwards, R.L., Cheng, H., Min, A., 2014. Changing amounts and sources of moisture in the U.S. southwest since the last glacial maximum in response to global climate change. Earth and Planetary Science Letters 401, 4756.Google Scholar
Flower, B.P., Hastings, D.W., Hill, H.W., Quinn, T.M., 2004. Phasing of deglacial warming and Laurentide Ice Sheet meltwater in the Gulf of Mexico. Geology 32, 597600.Google Scholar
Fowler, N.L., Dunlap, D.W., 1986. Grassland vegetation of the eastern Edwards Plateau. American Midland Naturalist 115, 46155.Google Scholar
Fredlund, G., 1998. Phytolith analysis. In: Collins, M.B., Bousman, C.B., Bailey, G.L. (Eds.), Wilson Leonard: An 11,000-Year Archeological Record of Hunter-Gatherers in Central Texas, Studies in Archaeology. Texas Archeological Research Laboratory, University of Texas at Austin, Austin, pp. 16371656.Google Scholar
Fredlund, G.G., Tieszen, L.L., 1997. Calibrating grass phytolith assemblages in climatic terms: application to late Pleistocene assemblages from Kansas and Nebraska. Palaeogeography, Palaeoclimatology, Palaeoecology 136, 199211.Google Scholar
Griffith, G., Bryce, S., Omnerik, J., Rogers, A., 2007. Ecoregions of Texas (Project Report). Texas Commission for Environmental Quality, Austin, TX. (Accessed April 1, 2019) https://www.epa.gov/eco-research/ecoregion-download-files-state-region-6#pane-41.Google Scholar
Grimm, E.C., 1987. CONISS: a Fortran 77 program for stratigraphically constrained cluster analysis by the method of incremental sum of squares. Computers and Geosciences 13, 1335.Google Scholar
Hafsten, U., 1961. Pleistocene development of vegetation and climate in the southern High Plains as evidence by pollen analysis. In: Wendorf, F. (Ed.), Paleoecology of the Llano Estacado. Museum of New Mexico Press, Santa Fe, NM, pp. 5991.Google Scholar
Hall, S.A., 1995. Late Cenozoic palynology in the south-central United States: cases of post-depositional pollen destruction. Palynology 19, 8593.Google Scholar
Hall, S.A., 2001. Geochronology and paleoenvironments of the glacial-age Tahoka Formation, Texas and New Mexico High Plains. New Mexico Geology 23, 7177.Google Scholar
Hall, S.A., 2005. Ice Age vegetation and flora of New Mexico. In: Lucas, S.G., Morgan, G.S., Zeigler, K.E. (Eds.), New Mexico's Ice Ages. New Mexico Museum of Natural History and Sciences Bulletin No. 28. New Mexico Museum of Natural History and Sciences, Albuquerque, NM, pp. 171183.Google Scholar
Hall, S.A., Valastro, S. Jr., 1995. Grassland vegetation in the southern Great Plains during the last glacial maximum. Quaternary Research 44, 237245.Google Scholar
Hammer, Ø., Parker, D., 2006. Paleontological Data Analysis. Blackwell, Oxford, UK.Google Scholar
Holliday, V.T., 1987. A reexamination of late-Pleistocene boreal forest reconstructions for the Southern High Plains. Quaternary Research 28, 238244.Google Scholar
Holliday, V.T., Meltzer, D.J., Mandel, R., 2011. Stratigraphy of the Younger Dryas chronozone and paleoenvironmental implications: central and southern Great Plains. Quaternary International 242, 520533.Google Scholar
Holloway, R.G., Bryant, V.M. Jr., 1984. Picea glauca pollen from late glacial deposits in central Texas. Palynology 8, 2132.Google Scholar
Holloway, R.G., Raab, L.M., Suckenrauth, R., 1987. Pollen analysis of the late-Holocene sediments from a central Texas bog. Texas Journal of Science 39, 7179.Google Scholar
Joines, J., 2011. 17,000 Years of Climate Change: The Phytolith Record from Hall's Cave, Texas. Master's thesis. Oklahoma State University, Stillwater.Google Scholar
Juggins, S., 2014. C2 Version 1.7.7. Craticula.ncl.ac.uk: Steve Juggins web pages at Newcastle University (accessed October 29, 2018). https://www.staff.ncl.ac.uk/stephen.juggins/.Google Scholar
Lanner, R.M., Van Devender, T.R., Richardson, D.M., 1998. The recent history of pinyon pines in the American Southwest. In: Richardson, D.M. (Ed.), Ecology and Biogeography of Pinus. Cambridge University Press, Cambridge, UK, pp. 171182.Google Scholar
Larson, D.A., Bryant, V.M., Patty, T.S., 1972. Pollen analysis of a central Texas bog. American Midland Naturalist 88, 358367.Google Scholar
Laskar, J., Robutel, P., Joutel, F., Tineau, M.G., Correia, A.C.M., Levrard, B., 2004. A long-term numerical solution for the insolation quantities of the earth. Astronomy and Astrophysics 428, 261265.Google Scholar
Ledig, F.T., Mápula-Larreta, M., Bermejo-Velázquez, B., Reyes-Hernández, V., Flores-López, C., Capó-Arteaga, M.A., 2000. Locations of endangered spruce populations in Mexico and the demography of Picea chihuahuana. Madroño 47, 7188.Google Scholar
Ledig, F.T., Rehfeldt, G.E., Sáenz-Romero, C., Flores-Lopez, C., 2010. Projections of suitable habitat for rare species under global warming scenarios. American Journal of Botany 97, 970987.Google Scholar
Lentfer, C.J., Boyd, W.E., 1998. A comparison of three methods for the extraction of phytoliths from sediments. Journal of Archaeological Science 25, 11591183.Google Scholar
Musgrove, M., Banner, J.L., Mack, L.E., Combs, D.M., James, E.W., Cheng, H., Edwards, R.L., 2001. Geochronology of late Pleistocene to Holocene speleothems from central Texas: implications for regional paleoclimate. Geological Society of America Bulletin 113, 15321543.Google Scholar
Nordt, L.C., Boutton, T.W., Jacob, J.S., Mandel, R.D., 2002. C4 plant productivity and climate-CO2 variations in south-central Texas during the late Quaternary. Quaternary Research 58, 182188.Google Scholar
Nordt, L., Von Fischer, J., Tieszen, L., Tubbs, J., 2008. Coherent changes in relative C4 plant productivity and climate during the late Quaternary in the North American Great Plains. Quaternary Science Reviews 27, 16001611.Google Scholar
Oldfield, F., Schoenwetter, J., 1975. Discussion of the pollen-analytical evidence. In: F. Wendorf, F., Hester, J. (Eds.), Late Pleistocene Environments of the Southern High Plains. Ft. Burgwin Research Center Publications 9. The Museum of New Mexico Press, Santa Fe, NM, pp. 149177.Google Scholar
Piperno, D. R., 2006. Phytoliths: A comprehensive guide for archaeologists and paleoecologists. Altamira Press, Lanham, MD.Google Scholar
Riskind, D.H., Diamond, D.D., 1988. An introduction to environments and vegetation. In: Amos, B.B., Gehlbach, F.R. (Eds.), Edwards Plateau Vegetation: Plant Ecological Studies in Central Texas. Baylor University Press, Waco, TX, pp. 116.Google Scholar
Roy, P.D., Rivero-Navarrete, A., Sánchez-Zavala, J.L., Beramendi-Orosco, L.E., Muthu-Sankar, G., Lozano-Santacruz, R., 2016. Atlantic Ocean modulated hydroclimate of the subtropical northeastern Mexico since the last glacial maximum and comparison with the southern US. Earth and Planetary Science Letters 434, 141150.Google Scholar
Rzedowski, J., 1981. Vegetacion de Mexico. Editorial Limusa, Mexico City.Google Scholar
Shaw, R., 2012. Guide to Texas Grasses. Texas A&M University Press, College Station.Google Scholar
Smith, F.A., Tomé, C.P., Elliott Smith, E.A., Lyons, S.K., Newsome, S.D., Stafford, T.W., 2016. Unraveling the consequences of the terminal Pleistocene megafauna extinction on mammal community assembly. Ecography 39, 223239.Google Scholar
Thompson, R.S., Anderson, K.H., Bartlein, P.J., 1999. Atlas of Relations between Climatic Parameters and Distributions of Important Trees and Shrubs in North America: Hardwoods. U.S. Geological Survey Professional Paper 1650-B. U.S. Geological Survey, Denver, CO.Google Scholar
Toomey, R.S. III. 1993. Late Pleistocene and Holocene Faunal and Environmental Changes at Hall's Cave, Kerr County, Texas. PhD dissertation, University of Texas at Austin, Austin.Google Scholar
Toomey, R.S. III, Blum, M.D., Valastro, S., 1993. Late Quaternary climates and environments of the Edwards Plateau, Texas. Global and Planetary Change 7, 299320.Google Scholar
U.S. Climate Data, 2019. U.S. Climate Data Version 2.3 (accessed April 1, 2019) https://www.usclimatedata.com/climate/kerrville/texas/united-states/ustx0689Google Scholar
Van Devender, T.R., 1990. Late Quaternary vegetation and climate of the Chihuahuan Desert, United States and Mexico. In: Betancourt, J.L., Van Devender, T.R., Martin, P.S. (Eds.), Packrat Middens: The Last 40,000 Years of Biotic Change. University of Arizona Press, Tucson, pp. 104133.Google Scholar
Van Devender, T.R., Martin, P.S., Phillips, A.M. III, Spaulding, W.G., 1978. Late Pleistocene communities from the Guadalupe Mountains, Culberson County, Texas. In: Wauer, R.H., Riskind, D.H. (Eds.), Transactions of the Symposium on the Biological Resources of the Chihuahuan Desert Region, United States and Mexico (Alpine, Texas, October 1974). National Park Service Transactions and Proceedings Series, No. 3. U.S. Department of the Interior, National Park Service, Washington, DC, pp. 107114.Google Scholar
Van Devender, T.R., Riskind, D.H., 1979. Late Pleistocene and early Holocene plant remains from Hueco Tanks State Historical Park: the development of a refugium. Southwestern Naturalist 24, 127140.Google Scholar
Watts, W.A., 1980. The late Quaternary vegetation history of the southeastern United States. Annual Review of Ecology and Systematics 11, 387409.Google Scholar
Williams, C., Flower, B.P., Hastings, D.W., 2012. Seasonal Laurentide Ice Sheet melting during the “Mystery Interval” (17.5–14.5 ka). Geology 40, 955958.Google Scholar
Wilson, L.R., 1966. Palynology of the Domebo site. In: Leonhardy, F.C. (Ed.), Domebo: A Paleo-indian Mammoth Kill in the Prairie-Plains. Contributions of the Museum of the Great Plains No. 1. Great Plains Historical Association, Lawton, OK, pp. 4451.Google Scholar
Wong, C.I., Banner, J.L., Musgrove, M., 2015. Holocene climate variability in Texas, USA: an integration of existing paleoclimate data and modeling with a new, high-resolution speleothem record. Quaternary Science Reviews 127, 155173.Google Scholar
Zhao, Z., Pearsall, D.M., 1998. Experiments for improving phytolith extraction from soils. Journal of Archaeological Science 25, 587598.Google Scholar
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