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Climate change in southern Illinois, USA, based on the age and δ13C of organic matter in cave sediments

Published online by Cambridge University Press:  20 January 2017

Samuel V. Panno ,
B. Brandon Curry ,
Hong Wang ,
Keith C. Hackley ,
Chao-Li Liu ,
Craig Lundstrom  and
Juanzuo Zhou
Samuel V. Panno*
Affiliation:
Illinois State Geological Survey, 615 E. Peabody Drive, Champaign, IL 61820, USA
B. Brandon Curry
Affiliation:
Illinois State Geological Survey, 615 E. Peabody Drive, Champaign, IL 61820, USA
Hong Wang
Affiliation:
Illinois State Geological Survey, 615 E. Peabody Drive, Champaign, IL 61820, USA
Keith C. Hackley
Affiliation:
Illinois State Geological Survey, 615 E. Peabody Drive, Champaign, IL 61820, USA
Chao-Li Liu
Affiliation:
Illinois State Geological Survey, 615 E. Peabody Drive, Champaign, IL 61820, USA
Craig Lundstrom
Affiliation:
Geology Department, University of Illinois, 1301 W. Green St. Urbana, IL 61801, USA
Juanzuo Zhou
Affiliation:
Geology Department, University of Illinois, 1301 W. Green St. Urbana, IL 61801, USA
*
*Corresponding author. Fax: (217) 244-2785.E-mail address:[email protected] (S.V. Panno).
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Abstract

Matrix-supported diamicton and uniform to laminated, silty, fine-grained sediment deposited from about 42,500 to 27,600 cal yr B.P. under slackwater conditions nearly filled two caves in southwestern Illinois. At some point, most of the sediment was flushed from the caves and from about 22,700 to 4000 cal yr B.P. floods deposited a drape of sandy and silty sediment on remnant slackwater successions, cobbly alluvium, and bedrock (especially from 7700 to 4000 cal yr B.P.). Clay mineral analyses of the slackwater cave sediment reveal a provenance of chiefly Petersburg Silt, a smectite- and illite-rich proglacial lacustrine unit present in the overlying Illinois Episode glacial succession. Today, remnants of the ancient subterranean slackwater deposits nearly fill several secondary passages and in at least two locations, cover a cobble-mantled strath terrace 1.3 to 1.5 m above active stream channels. Slumping and sinkhole formation appear to have been important mechanisms for deposition of the ancient subterranean deposits. Slumping of these surficial deposits and associated vegetation can occur along the flanks of sinkholes (in addition to sinkhole formation) and enter caves; however, the finer organics, some of them comminuted during transport into the caves, become part of the cave alluvium. This finer organic fraction is the modern analog of the humified organic matter disseminated in slackwater sediment dated in this investigation by radiocarbon methods. Twenty-four 14C ages on humified organic matter provide chronologic control. The δ13C values of the organic matter reflect the proportion of C4-type to C3-type vegetation growing in and around swallets and sinkholes at the time of redeposition. Drought-tolerant C4-type vegetation was more prevalent relative to C3-type vegetation from 42,500 to 31,200 cal yr B.P. compared to conditions from 28,800 cal yr B.P. to the present. The δ13C values are consistent with the results from other investigations of speleothems and organic matter from loessial paleosols.

Keywords

Cave sedimentsCarbon-14 datingSouthern IllinoisClimate changeIllinois Glacial EpisodeWisconsin Glacial EpisodeSubterranean slackwater deposits
Type
Research Article
Information
Quaternary Research , Volume 61 , Issue 3 , May 2004 , pp. 301 - 313
Copyright
University of Washington

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References

Aley, T., Moss, P., Aley, C., (2000). Delineation of recharge areas for four biologically significant cave systems in Monroe and St. Clair Counties, Illinois. Unpublished report by the Ozark Underground Laboratory to the Illinois Nature Preserves Commission and the Monroe County Soil and Water Conservation District.Google Scholar
Atlas, R.M, Bartha, R, (1998). Microbial Ecology: Fundamentals and Applications. Fourth ed. Addison Wesley Longman, Menlo Park., 694.Google Scholar
Baker, R.G, Maher, L.J, Chumbley, C.A, Van Zant, K.A, (1992). Patterns of Holocene environmental change in the Midwest. Quaternary Research. 37, 379389.Google Scholar
Barnhardt, M., (2001). Surficial geology of the Renault 7.5-minute quadrangle, Monroe County, Illinois. Illinois State Geological Survey Illinois Geologic Quadrangle Map.Google Scholar
Beck, J.W, Richards, D.A, Edwards, R.L, Silverman, B.W, Smart, P.L, Donahue, D.J, Hererra-Osterheld, S, Burr, G.S, Calsoyas, L, Jull, A.J.T, Biddulph, D, (2001). Extremely large variations of atmospheric 14C concentration during the last glacial period. Science. 292, 24532458.CrossRefGoogle ScholarPubMed
Coleman, D.D, (1973). Illinois State Geological Survey radiocarbon dates IV. Radiocarbon. 15, 7585.CrossRefGoogle Scholar
Curry, B.B, Anderson, T.F, Lohmann, K.C, (1997). Unusual carbon and oxygen isotopic ratios of ostracodal calcite from last interglacial (Sangamon Episode) lacustrine sediment in Raymond Basin, Illinois, USA. Journal of Paleolimnology. 17, 421435.CrossRefGoogle Scholar
Curry, B.B, Baker, R.G, (2000). Paleohydrology, vegetation, and climate during the last interglaciation (Sangamon Episode) in south-central Illinois. Palaeogeography, Palaeoclimatology, and Palaeoecology. 155, 5981.Google Scholar
Curry, B.B, Dorale, J.A, Henson, R.A, (2002). Function-fitting vegetation proxy record profiles of the Sangamon and Wisconsin Episodes from Missouri and Illinois. Geological Society of America, Abstracts with Programs. 34, 199.Google Scholar
Curry, B.B, Follmer, L.R, (1992). The last interglacial–glacial transition in Illinois: 123–25 ka. Clark, P.U, Lea, P.D, The Last Interglacial–Glacial Transition in North America: Boulder, CO. Geologic Society of America Special Paper. vol. 270, 7188.Google Scholar
Curry, B.B, Grimley, D.A, Andrews, A.C, Baker, R.G, (2001). Evidence for deep erosion by the Mississippi River near St. Louis under cold, dry conditions during the onset of the last glaciation. Geological Society of America Abstracts with Programs. 23, 4.Google Scholar
Denniston, R.F, Gonzalez, L.A, Semken, H.A Jr., Asmerom, Y, Baker, R.G, Recalli-Snyder, H, Reagan, M.K, Bettis, E.A III, (1999). Integrating stalagmite, vertebrate, and pollen sequences to investigate Holocene vegetation and climate change in the southern midwestern United States. Quaternary Research. 52, 381387.Google Scholar
Dorale, J.A, Edwards, L, Ito, E, Gonzalez, L.A, (1998). Climate and vegetation history of the midcontinent from 75 to 25 ka: a speleothem record from Crevice Cave, Missouri, USA. Science. 282, 18711874.Google Scholar
Dorale, J.A, Gonzalez, L.A, Reagan, M.K, Pickett, D.A, Murrell, T.M, Baker, R.G, (1992). A high-resolution record of Holocene climate change in speleothem calcite from Cold Water Cave, Northeast Iowa. Science. 258, 16261630.Google Scholar
Granger, D.E, Fabel, D, Palmer, A.N, (2001). Pliocene–Pleistocene incision of the Green River, Kentucky, determined from radioactive decay of cosmogenic 27Al and 10Be in Mammoth Cave sediments. GSA Bulletin. 113, 825836.Google Scholar
Grimley, D.A, Follmer, L.R, McKay, E.D, (1998). Magnetic susceptibility and mineral zonations controlled by provenance in loess along the Illinois and Central Mississippi Valleys. Quaternary Research. 49, 2436.Google Scholar
Grimley, D.A, Vepraskas, M.J, (2000). Magnetic susceptibility for use in delineating hydric soils. Soil Science Society of America Journal. 64, 21742180.Google Scholar
Grüger, E, (1972a). Late Quaternary vegetation development in south-central Illinois. Quaternary Research. 2, 217231.Google Scholar
Grüger, E, (1972b). Pollen and seed studies of Wisconsinan vegetation in Illinois, U.S.A.. Geological Society of America Bulletin. 83, 27152734.Google Scholar
Hajic, E.R, Johnson, W.H, Follmer, L.R, (1991). Quaternary deposits and landlords, confluence region of the Mississippi, Missouri, and Illinois Rivers, Missouri and Illinois: terraces and terrace problems. Midwest Friends of the Pleistocene 38th Field Conference, Department of Geology, University of Illinois at Urbana–Champaign. 106.Google Scholar
Hughes, R.E, Moore, D.M, Reynolds, R.C Jr., (1993). The nature, detection, occurrence, and origin of kaolinite/smectite. Murray, H, Bundy, W, Harvey, C, Kaolin Genesis and Utilization. Clay Minerals Society Special Publications. vol. 1, 291323.Google Scholar
Killey, M.M, (1998). Illinois' ice age legacy. Illinois State Geological Survey GeoScience Education Series. 14, 66.Google Scholar
Lasemi, A, Norby, R.D, Devera, J.A, Fouke, B.W, Leetaru, H.E, Denny, F.B, (1999). Middle Mississippian Carbonates and Siliclastics in Western Illinois. Illinois State Geological Survey Guidebook. vol. 31, 60.Google Scholar
Leigh, D.S, Knox, J.C, (1993). AMS radiocarbon age of the Upper Mississippi River Roxana Silt. Quaternary Research. 39, 282289.Google Scholar
Nelson, J.W, Devera, J.A, Jacobson, R.J, Luman, D.K, Pepper, R.A, Trask, B, Weibel, C.P, Follmer, L.R, Riggs, M.H, Esling, S.P, Henderson, E.D, Lannon, M.S, (1991). Geology of the Eddyville, Stonefort, 2nd Creal Springs quadrangles, southern Illinois. Illinois State Geological Survey Bulletin. vol. 96, 85.Google Scholar
Noakes, J.E, Kim, S.M, Akers, L.K, (1967). Recent improvements in benzene chemistry for radiocarbon dating. Geochemica et Cosmochemica Acta. 13, 10941096.Google Scholar
Ollendorf, A.L., (1993). . Changing landscapes in the American Bottom (USA): an interdisciplinary investigation with an emphasis on the late-prehistoric and early-historic periods. Ph.D. Thesis. Minneapolis–St. Paul: Univ. of Minnesota, ; 383.Google Scholar
Panno, S.V, Greenberg, S.E, Weibel, C.P, Gillespie, P.K, (2003a). A guide to the Illinois Caverns State Natural Area. Illinois State Geological Survey GeoScience Education Series 66.Google Scholar
Panno, S.V, Kelly, W.R, Weibel, C.P, Krapac, I.G, Sargent, S.L, (2003b). Water quality and agrichemical loading in two groundwater basins of Illinois’ sinkhole plain. Illinois State Geological Survey Environmental Geology Series. 156, 36.Google Scholar
Stuiver, M., Reimer, P.J., Reimer, R. , (2002). CALIB radiocarbon calibration, html version 4.3.Google Scholar
Teed, R, (2000). A >130,000-year-long pollen record from Pittsburg Basin, Illinois. Quaternary Research. 54, 264274.CrossRefGoogle Scholar
Wang, H, Follmer, L.R, Liu, C.-L, (2000). Isotope evidence of paleo-El Nino-southern oscillation cycles in loess–paleosol record in the central United States. Geology. 28, 771774.2.0.CO;2>CrossRefGoogle Scholar
Wang, H, Hackley, K.C, Panno, S.V, Coleman, D.D, Liu, C.-L, Brown, J, (2003). Pyrolysis combustion 14C dating of soil organic matter. Quaternary Research. 60, 348355.Google Scholar
Weibel, C.P., Panno, S.V., (1997). Karst terrains and carbonate bedrock of Illinois. Illinois State Geological Survey, Illinois Map Series 8, 1:500,000 Scale.Google Scholar
Wickham, S.S, Johnson, W.H, Glass, H.D, (1988). Regional geology of the Tiskilwa Till Member, Wedron Formation, northeastern Illinois. Illinois State Geological Survey Circular. 543, 35.Google Scholar
Wightman, P., (1982). Unpublished map of Fogelpole Cave.Google Scholar
Willman, H.B, Glass, H.D, Frye, J.C, (1966). Mineralogy of glacial tills and their weathering profiles in Illinois. Part II. Weathering profiles. Illinois State Geological Survey Circular. 400, 76.Google Scholar
Zhou, J., (2003). Isotope geochemistry of speleothem records from southern Illinois. Urbana–Champaign: Univ. of Illinois, Master's Thesis: 44.Google Scholar
Zhu, H, Baker, R.G, (1995). Vegetation and climate of the last glacial–interglacial cycle in Southern Illinois, USA. Journal of Paleolimnology. 14, 337354.Google Scholar