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Climatic and human controls on Holocene floodplain vegetation changes in eastern Pennsylvania based on the isotopic composition of soil organic matter

Published online by Cambridge University Press:  20 January 2017

Gary E. Stinchcomb ,
Timothy C. Messner ,
Forrest C. Williamson ,
Steven G. Driese  and
Lee C. Nordt
Gary E. Stinchcomb*
Affiliation:
Terrestrial Paleoclimatology Research Group, Department of Geology, Baylor University, Waco, TX 76798-7354, USA
Timothy C. Messner
Affiliation:
Archaeobiology Program, Department of Anthropology, Smithsonian National Museum of Natural History, Washington DC & Department of Anthropology, SUNY Potsdam, USA
Forrest C. Williamson
Affiliation:
Department of Statistical Science, Baylor University, Waco, TX, USA
Steven G. Driese
Affiliation:
Terrestrial Paleoclimatology Research Group, Department of Geology, Baylor University, Waco, TX 76798-7354, USA
Lee C. Nordt
Affiliation:
Terrestrial Paleoclimatology Research Group, Department of Geology, Baylor University, Waco, TX 76798-7354, USA
*
*Corresponding author.
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Abstract

A paleoenvironmental time-series spanning the Holocene was constructed using 29 radiocarbon ages and 149 standardized δ13Csom values from alluvial terrace profiles along the middle Delaware River valley. There is good agreement between increasing δ13Csom and Panicoideae phytolith concentrations, suggesting that variations in C4 biomass are a major contributor to changes in the soil δ13C. A measurement error deconvolution curve over time reveals two isotope stages (II–I), with nine sub-stages exhibiting variations in average δ13Csom (average %C4). Stage II, ~ 10.7–4.3 ka, shows above-average δ13Csom (increase %C4) values with evidence of an early Holocene warming and dry interval (sub-stage IIb, 9.8–8.3 ka) that coincides with rapid warming and cool-dry abrupt climate-change events. Sub-stage IId, 7.0–4.3 ka, is an above average δ13Csom (increase %C4) interval associated with the mid-Holocene warm-dry hypsithermal. The Stage II–I shift at 4.3 ka documents a transition toward below average δ13Csom (decrease %C4) values and coincides with decreasing insolation and hydroclimatic change. Sub-stages Ib and Id (above average %C4) coincide with the first documented occurrence of maize in the northeastern USA and a substantial increase in human population during the Late Woodland. These associations suggest that people influenced δ13Csom during the late Holocene.

Keywords

δ13C of soil organic matterAlluvial depositBuried soilHolocene paleoclimateEastern North America
Type
Research Article
Information
Quaternary Research , Volume 79 , Issue 3 , May 2013 , pp. 377 - 390
Copyright
University of Washington

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References

Baker, R.G., Fredlund, G.G., Mandel, R.D., and Bettis, E.A. Holocene environments of the central Great Plains: multi-proxy evidence from alluvial sequences, southeastern Nebraska. Quaternary International 67, (2000). 7588.Google Scholar
Balesdent, J., Girardin, C., and Mariotti, A. Site-related delta-c-13 of tree leaves and soil organic-matter in a temperate forest. Ecology 74, (1993). 17131721.Google Scholar
Barber, D., Dyke, A., Hillaire-Marcel, C., Jennings, A., Andrews, J., Kerwin, M., Bilodeau, G., McNeely, R., Southon, J., Morehead, M., and Gagnon, J. Forcing of the cold event of 8,200 years ago by catastrophic drainage of Laurentide lakes. Nature 400, (1999). 344348.Google Scholar
Beach, T., Luzzadder-Beach, S., Dunning, N., Jones, J., Lohse, J., Guderjan, T., Bozarth, S., Millspaugh, S., and Bhattacharya, T. A review of human and natural changes in Maya Lowland wetlands over the Holocene. Quaternary Science Reviews 28, (2009). 17101724.CrossRefGoogle Scholar
Beach, T., Luzzadder-Beach, S., Terry, R., Dunning, N., Houston, S., and Garrison, T. Carbon isotopic ratios of wetland and terrace soil sequences in the Maya Lowlands of Belize and Guatemala. Catena 85, (2011). 109118.Google Scholar
Blaauw, M. Methods and code for “classical” age-modelling of radiocarbon sequences. Quaternary Geochronology 5, (2010). 512518.Google Scholar
Bond, G., Kromer, B., Beer, J., Muscheler, R., Evans, M.N., Showers, W., Hoffmann, S., Lotti-Bond, R., Hajdas, I., and Bonani, G. Persistent solar influence on North Atlantic climate during the Holocene. Science 294, (2001). 21302136.CrossRefGoogle ScholarPubMed
Bond, G., Showers, W., Cheseby, M., Lotti, R., Almasi, P., deMenocal, P., Priore, P., Cullen, H., Hajdas, I., and Bonani, G. A pervasive millennial-scale cycle in North Atlantic Holocene and glacial climates. Science 278, (1997). 12571266.Google Scholar
Boutton, T.W. Stable carbon isotope ratios of soil organic matter and their use as indicators of vegetation and climate change. Boutton, T.W., and Yamasaki, S.-I. Mass Spectrometry of Soils. (1996). Marcel Dekker, Inc., New York. 4782.Google Scholar
Boutton, T.W., Nordt, L.C., and Kuehn, D.D. Late Quaternary vegetation and climate change in the North American Great Plains. International Symposium on Isotope Techniques in the Study of Past and Current Environmental Changes in the Hydrosphere and the Atmosphere. (1998). International Atomic Energy Agency, Vienna. 653662.Google Scholar
Bown, T., and Kraus, M. Integration of channel and floodplain suites.1. developmental sequence and lateral relations of alluvial paleosols RID C-3323–2008. Journal of Sedimentary Petrology 57, (1987). 587601.Google Scholar
Braun, E.L. Deciduous forests of eastern North America. (1950). McGraw-Hill Book Company, Inc., New York.Google Scholar
Bryant, V.M., and Holloway, R.G. Pollen records of late Quaternary North American sediment. (1985). American Association of Stratigraphic Palynologists Foundation, Dallas, Texas.Google Scholar
Carroll, R.J., Ruppert, D., Stefanski, L.A., and Crainiceanu, C.M. Measurement Error in Nonlinear Models: A Modern Perspective. 2nd ed. (2006). Chapman & Hall/CRC, Boca Raton.Google Scholar
Cerling, T.E., Wang, Y., and Quade, J. Expansion of C4 ecosystems as an indicator of global ecological change in the late Miocene. Nature 361, (1993). 344345.Google Scholar
Cordova, C.E., Johnson, W.C., Mandel, R.D., and Palmer, M.W. Late Quaternary environmental change inferred from phytoliths and other soil-related proxies: Case studies from the central and southern Great Plains, USA. Catena 85, (2011). 87108.Google Scholar
Custer, J.F. Prehistoric Cultures of Eastern Pennsylvania, Anthropological Series Number 7. (1996). Pennsylvania Historical and Museum Commission, Harrisburg.Google Scholar
Cyr, H., McNamee, C., Amundson, L., and Freeman, A. Reconstructing landscape and vegetation through multiple proxy indicators: a geoarchaeological examination of the St. Louis Site, Saskatchewan, Canada. Geoarchaeology 26, (2011). 165188.CrossRefGoogle Scholar
Denton, G.H., and Karlen, W. Holocene climatic variations – their pattern and possible cause. Quaternary Research 3, (1973). 155205.Google Scholar
Dijkstra, P., Ishizu, A., Doucett, R., Hart, S.C., Schwartz, E., Menyailo, O.V., and Hungate, B.A. C-13 and N-15 natural abundance of the soil microbial biomass. Soil Biology and Biochemistry 38, (2006). 32573266.Google Scholar
Driese, S.G., Li, Z.-H., and Horn, S.P. Late Pleistocene and Holocene climate and geomorphic histories as interpreted from a 23,000 14C yr B. P. paleosol and floodplain soils, southeastern West Virginia, USA. Quaternary Research 63, (2005). 136149.Google Scholar
Driese, S.G., Li, Z.-H., and McKay, L.D. Evidence for multiple, episodic, mid-Holocene hypsithermal recorded in two soil profiles along an alluvial floodplain catena, southeastern Tennessee, USA. Quaternary Research 69, (2008). 276291.CrossRefGoogle Scholar
Dzurec, R.S., Boutton, T.W., Caldwell, M.M., and Smith, B.N. Carbon isotope ratios of soil organic-matter and their use in assessing community composition changes in Curlew Valley, Utah. Oecologia 66, (1985). 1724.Google Scholar
Ehleringer, J.R., Hall, A.E., and Farquhar, G.D. Stable isotopes and plant carbon–water relations. (1993). Academic Press, San Diego.Google Scholar
Ehleringer, J., Cerling, T., and Helliker, B. C-4 photosynthesis, atmospheric CO2 and climate. Oecologia 112, (1997). 285299.Google Scholar
Ehleringer, J.R., Buchmann, N., and Flanagan, L.B. Carbon isotope ratios in belowground carbon cycle processes. Ecological Applications 10, (2000). 412422.Google Scholar
Ekdahl, E., Teranes, J., Guilderson, T., Turton, C., McAndrews, J., Wittkop, C., and Stoermer, E. Prehistorical record of cultural eutrophication from Crawford Lake, Canada. Geology 32, (2004). 745748.Google Scholar
Faison, E.K., Foster, D.R., Oswald, W.W., Hansen, B.C.S., and Doughty, E. Early Holocene openlands in southern New England. Ecology 87, (2006). 25372547.Google Scholar
Fang, X., Chua, T., Schmidt-Rohr, K., and Thompson, M.L. Quantitative 13C NMR of whole and fractionated Iowa Mollisols for assessment of organic matter composition. Geochimica et Cosmochimica Acta 74, (2010). 584598.CrossRefGoogle Scholar
Farquhar, G.D., Oleary, M.H., and Berry, J.A. On the relationship between carbon isotope discrimination and the inter-cellular carbon-dioxide concentration in leaves. Australian Journal of Plant Physiology 9, (1982). 121137.Google Scholar
Farquhar, G.D., Ehleringer, J.R., and Hubick, K.T. Carbon isotope discrimination and photosynthesis. Annual Review of Plant Physiology and Plant Molecular Biology 40, (1989). 503537.Google Scholar
Fesenmyer, K.A., and Christensen, N.L. Reconstructing Holocene fire history in a southern Appalachian forest using soil charcoal. Ecology 91, (2010). 662670.Google Scholar
Fredlund, G.G., and Tieszen, L.L. Phytolith and carbon isotope evidence for late Quaternary vegetation and climate change in the southern Black Hills, South Dakota. Quaternary Research 47, (1997). 206217.Google Scholar
Garten, C.T., Cooper, L.W., Post, W.M., and Hanson, P.J. Climate controls on forest soil C isotope ratios in the Southern Appalachian Mountains. Ecology 81, (2000). 11081119.Google Scholar
Hardt, B., Rowe, H.D., Springer, G.S., Cheng, H., and Edwards, R.L. The seasonality of east central North American precipitation based on three coeval Holocene speleothems from southern West Virginia. Earth and Planetary Science Letters 295, (2010). 342348.CrossRefGoogle Scholar
Hart, J.P., Brumbach, H.J., and Lusteck, R. Extending the phytolith evidence for early maize (Zea mays ssp. mays) and squash (Cucurbita sp.) in central New York. American Antiquity 72, (2007). 563583.Google Scholar
Hirschboeck, K.K. Flood hydroclimatology. Baker, V.R., Kochel, R.C., and Patton, P.C. Flood Geomorphology. (1988). John Wiley and Sons, 2749.Google Scholar
Holliday, V.T. Soils in archaeological research. (2004). Oxford University Press, Oxford.Google Scholar
Hou, J., Huang, Y., Shuman, B.N., Oswald, W.W., and Foster, D.R. Abrupt cooling repeatedly punctuated early-Holocene climate in eastern North America. The Holocene 22, (2012). 525529.Google Scholar
Huang, Y., Street-Perrott, F.A., Metcalfe, S.E., Brenner, M., Moreland, M., and Freeman, K.H. Climate change as the dominant control on glacial-interglacial variations in C-3 and C-4 plant abundance. Science 293, (2001). 16471651.Google Scholar
Hupp, C., and Osterkamp, W. Riparian vegetation and fluvial geomorphic processes. Geomorphology 14, (1996). 277295.Google Scholar
Kelly, E.F., Yonker, C., and Marino, B. Stable carbon isotope composition of paleosols: An application to Holocene. Swart, P.K., Lohmann, K.C., McKenzie, J., and Savin, S. Climate Change in Continental Isotopic Records. (1993). American Geophysical Union, Washington D.C.. 233240.Google Scholar
Kinsey, W.F., and McNett, C.W. Brodhead-Heller site, 36-Pi-7. Kinsey, W.F. Archaeology of the Upper Delaware River Valley. Anthropological Series of the Pennsylvania Historical and Museum Commission, No. 2, Harrisburg (1972). 199224.Google Scholar
Kirby, M.E., Patterson, W.P., Mullins, H.T., and Burnett, A.W. Post-Younger Dryas climate interval linked to circumpolar vortex variability: isotopic evidence from Fayetteville Green Lake, New York. Climate Dynamics 19, (2002). 321330.Google Scholar
Kocis, J.J., (2011). Late Pleistocene and Holocene hydroclimate change in the Southeastern United States: Sedimentary, pedogenic, and stable carbon isotope evidence in Tennessee River floodplain paleosols.: Master's Thesis completed at University of Tennessee, Knoxville.Google Scholar
Kraus, M.J., and Bown, T.M. Pedofacies analysis: A new approach to reconstructing ancient fluvial sequences. Reinhardt, J., and Sigleo, W.R. Paleosols and Weathering Through Geologic Time: Principles and Applications, Special Paper no. 216. (1988). Geological Society of America, Boulder, CO.Google Scholar
Kuchler, A.W. Potential natural vegetation of the coterminous United States. American Geographical Society, Special Publication No. 36. (1964). Google Scholar
Kutzbach, J.E. Monsoon climate of the early Holocene: climate experiment with the Earth's orbital parameters for 9000 years ago. Science 214, (1981). 5961.Google Scholar
Lee, J., Martin, A., Stiteler, J., (2010). Phase III archaeological data recovery of prehistoric site 28Wa290, Route I-80 truck weigh station project, Knowlton Township, Warren County, New Jersey. Prepared for the New Jersey Department of Transportation. On file, New Jersey Historic Preservation Office, Trenton. Prepared by Hunter Research, Inc.Google Scholar
Li, Y.-X., Yu, Z., and Kodama, K.P. Sensitive moisture response to Holocene millennial-scale climate variations in the Mid-Atlantic region, USA. The Holocene 17, (2007). 38.Google Scholar
Lu, H., and Liu, K.-B. Phytoliths of common grasses in coastal environments of southeastern USA. Estuarine, Coastal and Shelf Science 58, (2003). 587600.Google Scholar
Melillo, J., Aber, J., Linkins, A., Ricca, A., Fry, B., and Nadelhoffer, K. Carbon and nitrogen dynamics along the decay continuum — plant litter to soil organic-matter. Plant and Soil 115, (1989). 189198.CrossRefGoogle Scholar
Millard, P., Midwood, A.J., Hunt, J.E., Barbour, M.M., and Whitehead, D. Quantifying the contribution of soil organic matter turnover to forest soil respiration, using natural abundance δ13C. Soil Biology and Biochemistry 42, (2010). 935943.Google Scholar
Mullins, H.T., Patterson, W.P., Teece, M.A., and Burnett, A.W. Holocene climate and environmental change in central New York (USA). Journal of Paleolimnology 45, (2011). 243256.Google Scholar
Munoz, S.E., and Gajewski, K. Distinguishing prehistoric human influence on late-Holocene forests in southern Ontario, Canada. The Holocene 20, (2010). 967981.Google Scholar
Nadelhoffer, K.F., and Fry, B. Controls on natural N-15 and C-13 abundances in forest soil organic-matter. Soil Science Society of America Journal 52, (1988). 16331640.CrossRefGoogle Scholar
Newby, P.E., Donnelly, J.P., Shuman, B.N., and MacDonald, D. Evidence of centennial-scale drought from southeastern Massachusetts during the Pleistocene/Holocene transition. Quaternary Science Reviews 28, (2009). 16751692.Google Scholar
Newby, P.E., Shuman, B.N., Donnelly, J.P., and MacDonald, D. Repeated century-scale droughts over the past 13,000 yr near the Hudson River watershed, USA. Quaternary Research 75, (2011). 523530.Google Scholar
NOAA, http://www1.ncdc.noaa.gov/pub/data/normals/1981-2010/products/ (2011). (Accessed on 20 Feb 2012) Google Scholar
Nordt, L.C., Boutton, T.W., Hallmark, C.T., and Waters, M.R. Late Quaternary vegetation and climate changes in Central Texas based on the isotopic composition of organic-carbon. Quaternary Research 41, (1994). 109120.CrossRefGoogle Scholar
Nordt, L.C., Boutton, T.W., Jacob, J.S., and Mandel, R.D. C-4 plant productivity and climate—CO2 variations in south-central Texas during the late Quaternary. Quaternary Research 58, (2002). 182188.Google Scholar
Nordt, L., von Fischer, J., and Tieszen, L. Late Quaternary temperature record from buried soils of the North American Great Plains. Geology 35, (2007). 159162.Google Scholar
Nordt, L., Von Fischer, J., Tieszen, L., and Tubbs, J. Coherent changes in relative C-4 plant productivity and climate during the late Quaternary in the North American Great Plains. Quaternary Science Reviews 27, (2008). 16001611.Google Scholar
Parris, A.S., Bierman, P.R., Noren, A.J., Prins, M.A., and Lini, A. Holocene paleostorms identified by particle size signatures in lake sediments from the northeastern United States. Journal of Paleolimnology 43, (2010). 2949.Google Scholar
Perles, S.J., Podniesinski, G.S., Eastman, E., Sneddon, L.A., and Gawler, S.C. Classification and mapping of vegetation and fire fuel models at Delaware Water Gap National Recreation Area: Volume 1 of 2. Technical Report NPS/NER/NRTR—2007/076. (2007). National Park Service, Philadelphia, PA.Google Scholar
Peros, M.C., Munoz, S.E., Gajewski, K., and Viau, A.E. Prehistoric demography of North America inferred from radiocarbon data. Journal of Archaeological Science 37, (2010). 656664.Google Scholar
Peuke, A.D., Gessler, A., and Rennenberg, H. The effect of drought on C and N stable isotopes in different fractions of leaves, stems and roots of sensitive and tolerant beech ecotypes. Plant, Cell and Environment 29, (2006). 823835.Google Scholar
Piperno, D.R. Phytoliths: A comprehensive guide for archaeologists and paleoecologists. (2006). AltaMira Press, Lanham, Maryland.Google Scholar
Reimer, P.J., Baillie, M.G.L., Bard, E., Bayliss, A., Beck, J.W., Blackwell, P.G., Ramsey, C.B., Buck, C.E., Burr, G.S., Edwards, R.L., Friedrich, M., Grootes, P.M., Guilderson, T.P., Hajdas, I., Heaton, T.J., Hogg, A.G., Hughen, K.A., Kaiser, K.F., Kromer, B., McCormac, F.G., Manning, S.W., Reimer, R.W., Richards, D.A., Southon, J.R., Talamo, S., Turney, C.S.M., van der Plicht, J., and Weyhenmeye, C.E. IntCal09 and Marine09 radiocarbon age calibration curves, 0–50,000 years cal BP RID F-4952-2011 RID B-7298-2008. Radiocarbon 51, (2009). 11111150.Google Scholar
Richards, K., Brasington, J., and Hughes, F. Geomorphic dynamics of floodplains: ecological implications and a potential modelling strategy RID F-4868-2010. Freshwater Biology 47, (2002). 559579.Google Scholar
Ripley, B., Frole, K., and Gilbert, M. Differences in drought sensitivities and photosynthetic limitations between co-occurring C3 and C4 (NADP-ME) Panicoid grasses. Annals of Botany 105, (2010). 493503.Google Scholar
Runge, J. Holocene landscape history and palaeohydrology evidenced by stable carbon isotope (delta C-13) analysis of alluvial sediments in the Mbari valley (5° N/23° E), Central African Republic. Catena 48, (2002). 6787.Google Scholar
Sage, R. The evolution of C(4) photosynthesis. The New Phytologist 161, (2004). 341370.Google Scholar
Schaetzl, R.J., and Anderson, S. Soils: Genesis and geomorphology. (2005). Elsevier Inc., Cambridge. (832 pp.)Google Scholar
Schoeneberger, P.J., Wysocki, D.A., Benham, E.C., and Broderson, W.D. Field book for describing and sampling soils, version 2.0. (2002). Natural Resources Conservation Service, National Soil Survey Center, Lincoln, NE.Google Scholar
Schuldenrein, J. Landscape change, human occupation, and archaeological site preservation at the glacial margin: Geoarchaeological perspectives from the Sandts Eddy Site (36 Nm12), Middle Delaware River valley, Pennsylvania. Cremeens, D.L., and Hart, J.P. Geoarchaeology of Landscapes in the Glaciated Northeast. Proceedings of a symposium held at the New York Natural History conference VI (2003). The New York State Education Department, New York, New York State Museum. 181210.Google Scholar
Schulze, E.D., Ellis, R., Schulze, W., and Trimborn, P. Diversity, metabolic types and delta C-13 carbon isotope ratios in the grass flora of Namibia in relation to growth form, precipitation and habitat conditions. Oecologia 106, (1996). 352369.Google Scholar
Scully, R., and Arnold, R. Holocene alluvial stratigraphy in the Upper Susquehanna River basin, New York. Quaternary Research 15, (1981). 327344.Google Scholar
Sedov, S., Solleiro-Rebolledo, E., Morales-Puente, P., Arias-Herreia, A., Vallejo-Gomez, E., and Jasso-Castaneda, C. Mineral and organic components of the buried paleosols of the Nevado de Toluca, Central Mexico as indicators of paleoenvironments and soil evolution. Quaternary International 106, (2003). 169184.Google Scholar
Shuman, B., and Donnelly, J.P. The influence of seasonal precipitation and temperature regimes on lake levels in the northeastern United States during the Holocene. Quaternary Research 65, (2006). 4456.Google Scholar
Shuman, B., and Plank, C. Orbital, ice sheet, and possible solar controls on Holocene moisture trends in the North Atlantic drainage basin. Geology 39, (2011). 151154.Google Scholar
Shuman, B., Newby, P., Huang, Y.S., and Webb, T. Evidence for the close climatic control of New England vegetation history. Ecology 85, (2004). 12971310.Google Scholar
Shuman, B.N., Newby, P., and Donnelly, J.P. Abrupt climate change as an important agent of ecological change in the Northeast U.S. throughout the past 15,000 years. Quaternary Science Reviews 28, (2009). 16931709.Google Scholar
Smith, J.A., Baeck, M.L., Villarini, G., and Krajewski, W.F. The hydrology and hydrometeorology of flooding in the Delaware River Basin. Journal of Hydrometeorology 11, (2010). 841859.Google Scholar
Southgate, E.W.B. Herbaceous plant communities on the Delaware River floodplain, New Jersey, during the Mid-Holocene. The Journal of the Torrey Botanical Society 137, (2010). 252262. (Russell) CrossRefGoogle Scholar
Springer, G.S., White, D.M., Rowe, H.D., Hardt, B., Mihimdukulasooriya, L.N., Cheng, H., and Edwards, R.L. Multiproxy evidence from caves of Native Americans altering the overlying landscape during the late Holocene of east-central North America. The Holocene 20, (2010). 275283.Google Scholar
Springer, G.S., Rowe, H.D., Hardt, B., Edwards, R.L., and Cheng, H. Solar forcing of Holocene droughts in a stalagmite record from West Virginia in east-central North America. Geophysical Research Letters 35, (2008). 5 Google Scholar
Stewart, M., Custer, J., and Kline, D. A deeply stratified archaeological and sedimentary sequence in the Delaware River valley of the Middle Atlantic region, United States. Geoarchaeology 6, (1991). 169182.Google Scholar
Stewart, G.R., Turnbull, M.H., Schmidt, S., and Erskine, P.D. C-13 natural-abundance in plant-communities along a rainfall gradient - a biological integrator of water availability. Australian Journal of Plant Physiology 22, (1995). 5155.Google Scholar
Stinchcomb, G.E., Messner, T.C., Driese, S.G., Nordt, L.C., and Stewart, R.M. Pre-colonial (AD 1100-1600) sedimentation related to prehistoric maize agriculture and climate change in eastern North America. Geology 39, (2011). 363366.Google Scholar
Stinchcomb, G.E., Driese, S.G., Nordt, L.C., and Allen, P.A. A mid to late Holocene history of floodplain and terrace reworking along the middle Delaware River valley, USA. Geomorphology 169–170, (2012). 123141.Google Scholar
Stoops, G. Guidelines for Analysis and Description of Soil and Regolith Thin Sections. (2003). Soil Science Society of America, Inc., Wisconsin, USA.Google Scholar
Teeri, J.A., and Stowe, L.G. Climatic patterns and distribution of C4 grasses in North-America. Oecologia 23, (1976). 112.Google Scholar
Thieme, D. Historic and possible prehistoric impacts on floodplain sedimentation, North Branch of the Susquehanna River Valley, Pennsylvania, U.S.A.. Maddy, D. et al. River basin sediment systems. (2001). Balkema, Rotterdam. 375403.Google Scholar
Tieszen, L.L., Reed, B.C., Bliss, N.B., Wylie, B.K., and DeJong, D.D. NDVI, C-3 and C-4 production, and distributions in Great Plains grassland land cover classes. Ecological Applications 7, (1997). 5978.Google Scholar
Trewartha, G.T. Elements of physical geography. (1957). McGraw-Hill Book Company, Inc., Google Scholar
Twiss, P.C., Suess, E., and Smith, R.M. Morphological classification of grass phytoliths. Soil Science Society of America Proceedings 33, (1969). 109115.Google Scholar
Vento, F.J., Rollins, H.B., Stewart, M., Raber, P., and Johnson, W. Genetic stratigraphy, paleosol development and the burial of archaeological sites in the Susquehanna, Delaware, and upper Ohio drainage basins, Pennsylvania. (1989). Bureau for Historic Preservation, Grants Office, William Penn Museum and Historical Commission, Google Scholar
Viau, A.E., Gajewski, K., Fines, P., Atkinson, D.E., and Sawada, M.C. Widespread evidence of 1500 yr climate variability in North America during the past 14 000 yr. Geology 30, (2002). 455458.Google Scholar
Viau, A.E., Gajewski, K., Sawada, M.C., and Fines, P. Millennial-scale temperature variations in North America during the Holocene. Journal of Geophysical Research-Atmospheres 111, (2006). Google Scholar
Von Fischer, J., and Tieszen, L. Carbon-isotope characterization of vegetation and soil organic-matter in subtropical forests in Luquillo, Puerto-Rico RID B-5443-2008. Biotropica 27, (1995). 138148.Google Scholar
von Fischer, J.C., Tieszen, L.L., and Schimel, D.S. Climate controls on C-3 vs. C-4 productivity in North American grasslands from carbon isotope composition of soil organic matter. Global Change Biology 14, (2008). 11411155.Google Scholar
Wang, X.-F., and Wang, B. Deconvolution estimation in measurement error models: the R Package Decon. Journal of Statistical Software 39, (2011). i10 Google Scholar
Way, J.H. Appalachian Mountain section of the Ridge and Valley province. Shultz, C.H. The Geology of Pennsylvania. (1999). Pennsylvania Geological Survey and Pittsburgh Geological Society, Harrisburg. 352361.Google Scholar
Webb, E.A., Schwarcz, H.P., and Healy, P.F. Detection of ancient maize in lowland Maya soils using stable carbon isotopes: evidence from Caracol, Belize. Journal of Archaeological Science 31, (2004). 10391052.Google Scholar
Wendland, W.M., and Bryson, R.A. Dating climatic episodes of the Holocene. Quaternary Research 4, (1974). 9 (&) Google Scholar
Williams, D., and Ehleringer, J. Carbon isotope discrimination in three semi-arid woodland species along a monsoon gradient. Oecologia 106, (1996). 455460.Google Scholar
Witte, R.W. Late Wisconsinan deglaciation and postglacial history of Minisink Valley: Delaware. Inners, J.D., and Fleeger, G.M. 2001 - A Delaware River odyssey, Guidebook, 66th Annual Conference of Pennsylvania Geologists. (2001). 99118. (Shawnee-on-Delaware, PA) Google Scholar
Wright, D.R., Terry, R.E., and Eberl, M. Soil properties and stable carbon isotope analysis of landscape features in the Petexbatun Region of Guatemala. Geoarchaeology: An International Journal 24, (2009). 466491.CrossRefGoogle Scholar
Zhao, C., Yu, Z.C., Ito, E., and Zhao, Y. Holocene climate trend, variability, and shift documented by lacustrine stable-isotope record in the northeastern United States. Quaternary Science Reviews 29, (2010). 18311843.Google Scholar
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