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Unprecedented last-glacial mass accumulation rates determined by luminescence dating of loess from western Nebraska

Published online by Cambridge University Press:  20 January 2017

Helen M. Roberts ,
Daniel R. Muhs ,
Ann G. Wintle ,
Geoff A. T. Duller  and
E. Arthur Bettis III
Helen M. Roberts*
Affiliation:
Institute of Geography and Earth Sciences, University of Wales, Aberystwyth SY23 3DB, UK
Daniel R. Muhs
Affiliation:
U.S. Geological Survey, MS 980, Box 25046, Federal Center, Denver, CO 80225, USA
Ann G. Wintle
Affiliation:
Institute of Geography and Earth Sciences, University of Wales, Aberystwyth SY23 3DB, UK
Geoff A. T. Duller
Affiliation:
Institute of Geography and Earth Sciences, University of Wales, Aberystwyth SY23 3DB, UK
E. Arthur Bettis III
Affiliation:
Department of Geoscience, University of Iowa, Iowa City, IA 52242, USA
*
*Corresponding author. Fax: +44-1970-622659. Email Address:hmr@aber.ac.uk
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Abstract

A high-resolution chronology for Peoria (last glacial period) Loess from three sites in Nebraska, midcontinental North America, is determined by applying optically stimulated luminescence (OSL) dating to 35–50 μm quartz. At Bignell Hill, Nebraska, an OSL age of 25,000 yr near the contact of Peoria Loess with the underlying Gilman Canyon Formation shows that dust accumulation occurred early during the last glacial maximum (LGM), whereas at Devil’s Den and Eustis, Nebraska, basal OSL ages are significantly younger (18,000 and 21,000 yr, respectively). At all three localities, dust accumulation ended at some time after 14,000 yr ago. Mass accumulation rates (MARs) for western Nebraska, calculated using the OSL ages, are extremely high from 18,000 to 14,000 yr—much higher than those calculated for any other pre-Holocene location worldwide. These unprecedented MARs coincide with the timing of a mismatch between paleoenvironmental evidence from central North America, and the paleoclimate simulations from atmospheric global circulation models (AGCMs). We infer that the high atmospheric dust loading implied by these MARs may have played an important role, through radiative forcing, in maintaining a colder-than-present climate over central North America for several thousand years after summer insolation exceeded present-day values.

Keywords

Dust fluxPeoria LoessOptically stimulated luminescence datingOSLQuartzCoarse-silt-sized grainsMass accumulation rate (MAR)Climate forcing
Type
Articles
Information
Quaternary Research , Volume 59 , Issue 3 , May 2003 , pp. 411 - 419
Copyright
Elsevier Science (USA)

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References

Aitken, M.J Thermoluminescence Dating. (1985). Academic Press, London.Google Scholar
Aitken, M.J An Introduction to Optical Dating. (1998). Oxford University Press, Oxford.Google Scholar
Aleinikoff, J.N, Muhs, D.R, and Fanning, C.M Isotopic evidence for the sources of late Wisconsin (Peoria) Loess. implications for paleoclimate. Busacca, A Dust Aerosols, Loess Soils & Global Change. (1998). Washington State University, College of Agriculture and Home Economics Miscellaneous Publication No. MISC0190, Colorado and Nebraska. 124 127.Google Scholar
Aleinikoff, J.N, Muhs, D.R, Sauer, R.R, and Fanning, C.M Late Quaternary loess in northeastern Colorado. Part II. Pb isotopic evidence for the variability of loess sources. Geological Society of America Bulletin 111, (1999). 1876 1883.Google Scholar
Antoine, P, Rousseau, D.-D, Zöller, L, Lang, A, Munaut, A.-V, Hatté, C, and Fontugne, M High-resolution record of the last interglacial-glacial cycle in the Nussloch loess-paleosol sequences, Upper Rhine area, Germany. Quaternary International 76/77, (2001). 211 229.Google Scholar
Baker, R.G, Maher, L.J, Chumbley, C.A, and Van Zant, K.L Patterns of Holocene environmental-change in the Midwestern United-States. Quaternary Research 37, (1992). 379 389.Google Scholar
Baker, R.G, Sullivan, A.E, Hallberg, G.R, and Horton, D.G Vegetational changes in western Illinois during the onset of late Wisconsinan glaciation. Ecology 70, (1989). 1363 1376.Google Scholar
Baker, R.G, Rhodes, R.S II, Schwert, D.P, Ashworth, A.C, Frest, T.J, Hallberg, G.R, and Janssens, J.A A full-glacial biota from south-eastern Iowa, USA. Journal of Quaternary Science 1, (1986). 91 107.Google Scholar
Banerjee, D, Murray, A.S, Bøtter-Jensen, L, and Lang, A Equivalent dose estimation using a single aliquot of polymineral fine grains. Radiation Measurements 33, (2001). 73 93.Google Scholar
Bartlein, P.J, Anderson, K.H, Anderson, P.M, Edwards, M.E, Mock, C.J, Thompson, R.S, Webb, R.S, Webb, T III, and Whitlock, C Paleoclimate simulations for North America over the past 21,000 years. features of the simulated climate and comparisons with paleoenvironmental data. Quaternary Science Reviews 17, (1998). 549 585.Google Scholar
Berger, A, and Loutre, M.F Insolation values for the climate of the last 10 million years. Quaternary Science Reviews 10, (1991). 297 Google Scholar
Berger, G.W, Mulhern, P.J, and Huntley, D.J Isolation of silt-sized quartz from sediments. Ancient TL 11, (1980). 8 9.Google Scholar
Bettis, E.A. III, Muhs, D.R., Roberts, H.M., and Wintle, A.G. (2003). Last Glacial loess in the conterminous U.S.A.. Quaternary Science Reviews, in press Google Scholar
Eden, D.N, Froggatt, P.C, and McIntosh, P.D The distribution and composition of volcanic glass in late Quaternary loess deposits of southern South Island, New Zealand, and some possible correlations. New Zealand Journal of Geology and Geophysics 35, (1992). 69 79.Google Scholar
FAUNMAP Working Group. (1994). FAUNMAP: a Database documenting Late Quaternary distributions of mammal species in the United States. Illinois State Museum Scientific Paper 25 Google Scholar
Frye, J.C, Leonard, A.B, Willman, H.B, Glass, H.D, and Follmer, L.R Late Woodfordian Jules Soil and associated molluscan faunas. Illinois State Geological Survey Circular 486, (1974). 1 11.Google Scholar
Hallberg, G.R, Lineback, J.A, Mickelson, D.M, Knox, J.C, Goebel, J.E, Hobbs, H.C, Whitfield, J.W, Ward, R.A, Boellstorf, J.D, Swinehart, J.B, and Dreeszen, V.H Quaternary geologic map of the Des Moines 4° × 6° quadrangle. (1991). U.S. Geological Survey Miscellaneous Investigations Series Map I-1420 (NK-15), scale 1:1,000,000, Google Scholar
Harrison, S, Kohfeld, K.E, Roelandt, C, and Claquin, T The role of dust in climate changes today, at the last glacial maximum and in the future. Earth Science Reviews 54, (2001). 43 80.Google Scholar
Hatté, C, Fontugne, M, Rousseau, D.-D, Antoine, P, Zöller, L, Tisnérat-Laborde, N, and Bentaleb, I δ13C variations of loess organic matter as a record of the vegetation response to climatic changes during the Weichselian. Geology 26, (1998). 583 586.2.3.CO;2>CrossRefGoogle Scholar
Johnson, W.C Surficial geology and stratigraphy of Phillips County, Kansas, with emphasis on the Quaternary Period. Kansas Geological Survey Technical Series 1, (1993). 66 p Google Scholar
Johnson, W.C, and Willey, K.L Isotopic and rock magnetic expression of environmental change at the Pleistocene-Holocene transition in the central Great Plains. Quaternary International 67, (2000). 89 106.Google Scholar
Kohfeld, K.E, and Harrison, S.P How well can we simulate past climates? Evaluating the models using global paleoenvironmental datasets. Quaternary Science Reviews 19, (2000). 321 346.Google Scholar
Kohfeld, K.E, and Harrison, S.P DIRTMAP. the geological record of dust. Earth Science Reviews 54, (2001). 81 114.Google Scholar
Kutzbach, J, Gallimore, R, Harrison, S, Behling, P, Selin, R, and Laarif, F Climate and biome simulations for the past 21,000 years. Quaternary Science Revews 17, (1998). 473 506.Google Scholar
Lauriol, B, Cabana, Y, Cinq-Mars, J, Geurts, M.-A, and Grimm, F.W Cliff-top eolian deposits and associated molluscan assemblages as indicators of Late Pleistocene and Holocene environments in Beringia. Quaternary International 87, (2002). 59 79.Google Scholar
Leonard, A.B Stratigraphic zonation of the Peoria Loess in Kansas. Journal of Geology 59, (1951). 323 332.Google Scholar
Leonard, A.B, and Frye, J.C Wisconsinan molluscan faunas of the Illinois Valley region. Illinois State Geological Survey Circular 304, (1960). 1 32.Google Scholar
Licciardi, J.M, Clark, P.U, Jenson, J.W, and Macayeal, D.R Deglaciation of a soft-bedded Laurentide Ice Sheet. Quaternary Science Reviews 17, (1998). 427 448.Google Scholar
Lindholm, G.F., Thomas, L.A., Davidson, D.T., Handy, R.L., Roy, C.J., (1959). Silts near Big Delta and Fairbanks. in: Davidson, D.T., Roy, C.J. (Eds.), The Geology and Engineering Characteristics of Some Alaskan Soils, Iowa State University Bulletin 186., pp. 3370.Google Scholar
Maat, P.B, and Johnson, W.C Thermoluminescence and new 14C age estimates for late Quaternary loesses in southwestern Nebraska. Geomorphology 17, (1996). 115 128.Google Scholar
Mahowald, N, Kohfeld, K, Hansson, M, Balkanski, Y, Harrison, S.P, Prentice, I.C, Schulz, M, and Rodhe, H Dust sources and deposition during the last glacial maximum and current climate. a comparison of model results with paleodata from ice cores and marine sediments. Journal of Geophysical Research-Atmospheres 104, (1999). 15895 15916.Google Scholar
Martin, C.W Radiocarbon ages on late Pleistocene loess stratigraphy of Nebraska and Kansas, central Great Plains, U.S.A. Quaternary Science Reviews 12, (1993). 179 188.Google Scholar
Mason, J.A Transport direction of Peoria Loess in Nebraska and implications for loess sources on the central Great Plains. Quaternary Research 56, (2001). 79 86.Google Scholar
McFadden, J.D, and Ragotzkie, R.A Climatological significance of albedo in central Canada. Journal of Geophysical Research 72, (1967). 1135 1143.CrossRefGoogle Scholar
Muhs, D.R, Bettis, E.A III Geochemical variations in Peoria Loess of western Iowa indicate paleowinds of midcontinental North America during last glaciation. Quaternary Research 53, (2000). 49 61.Google Scholar
Muhs, D.R, Aleinikoff, J.N, Stafford, T.W, Kihl, R, Been, J, Mahan, S.A, and Cowherd, S Late Quaternary loess in northeastern Colorado. Part I. Age and paleoclimatic significance. Geological Society of America Bulletin 111, (1999). 1861 1875.Google Scholar
Musson, F.M, and Wintle, A.G Luminescence dating of the loess profile at Dolní Vestonice, Czech Republic. Quaternary Geochronology (Quaternary Science Reviews) 13, (1994). 411 416.Google Scholar
Nawrocki, J, Bakhmutov, V, Bogucki, A, and Dolecki, L The paleo- and petromagnetic record in the Polish and Ukrainian loess-paleosol sequences. Physics and Chemistry of the Earth 24, (1999). 773 777.Google Scholar
Overpeck, J, Rind, D, Lacis, A, and Healy, R Possible role of dust-induced regional warming in abrupt climate change during the last glacial period. Nature 384, (1996). 447 449.Google Scholar
Palmer, A.S, and Pillans, B.J Record of climatic fluctuations from ca. 500 ka loess deposits and paleosols near Wanganui, New Zealand. Quaternary International 34–36, (1996). 155 162.Google Scholar
Péwé, T.L., (1975). Quaternary geology of Alaska. Geological Survey Professional Paper 835 Google Scholar
Péwé, T.L, and Holmes, G.W Geology of the Mt. Hayes D-4 quadrangle. (1964). U.S. Geological Survey Miscellaneous Geologic Investigations Map I-394, scale 1:63,360, Alaska.Google Scholar
Pillans, B, McGlone, M, Palmer, A, Mildenhall, D, Alloway, B, and Berger, G The Last Glacial Maximum in central and southern North Island, New Zealand. a paleoenvironmental reconstruction using the Kawakawa Tephra Formation as a chronostratigraphic marker. Palaeogeography, Palaeoclimatology, Palaeoecology 101, (1993). 283 304.Google Scholar
Prescott, J.R, and Hutton, J.T Cosmic ray contributions to dose rates for luminescence and ESR dating. large depths and long-term time variations. Radiation Measurements 23, (1994). 497 500.Google Scholar
Pye, K, Winspear, N.R, and Zhou, L.P Thermoluminescence ages of loess and associated sediments in central Nebraska, USA. Palaeogeography, Palaeoclimatology, Palaeoecology 118, (1995). 73 87.Google Scholar
Rees-Jones, J Optical dating of young sediments using fine-grain quartz. Ancient TL 13, (1995). 9 13.Google Scholar
Roberts, H.M, and Wintle, A.G Equivalent dose determinations for polymineralic fine-grains using the SAR protocol. application to a Holocene sequence of the Chinese Loess Plateau. Quaternary Science Reviews 20, (2001). 859 863.Google Scholar
Rousseau, D.-D, and Kukla, G Late Pleistocene climate record in the Eustis loess section, Nebraska, based on land snail assemblages and magnetic susceptibility. Quaternary Research 42, (1994). 176 187.Google Scholar
Ruhe, R.V Quaternary Landscapes in Iowa. (1969). Iowa State University Press, Ames, IA.Google Scholar
Schwert, D.P, Torpen-Kreft, H.J, and Hajic, E.R Characterization of the Late-Wisconsinan Tundra/Forest Transition in Midcontinental North America using assemblages of beetle fossils. Quaternary Proceedings 5, (1997). 237 243.Google Scholar
Stuiver, M, Reimer, P.J, Bard, E, Beck, J.W, Burr, G.S, Hughen, K.A, Kromer, B, McCormac, G, Van der Plicht, J, and Spurk, M INTCAL98 radiocarbon age calibration, 24,000-0 cal BP. Radiocarbon 40, (1998). 1041 1083.Google Scholar
Sümegi, P, and Rudner, Z.E In situ charcoal fragments as remains of natural wild fires in the upper Würm of the Carpathian Basin. Quaternary International 76/77, (2001). 165 176.Google Scholar
Sun, J.M., Kohfeld, K.E., Harrison, S.P., (2000). Records of aeolian dust deposition on the Chinese Loess Plateau during the Late Quaternary. Max-Planck Institut für Biogeochemie Technical Report 1 Google Scholar
Swineford, A, and Frye, J.C Petrography of the Peoria Loess in Kansas. Journal of Geology 59, (1951). 306 322.Google Scholar
Swinehart, J.B, Dreeszen, V.H, Richmond, G.M, Tipton, M.J, Bretz, R, Steece, F.V, Hallberg, G.R, and Goebel, J.E Quaternary geologic map of the Platte River 4° × 6° quadrangle. (1994). U.S. Geological Survey Miscellaneous Investigations Series Map I-1420 (NK-14), scale 1:1,000,000, Google Scholar
Swinehart, J.B, Loope, D, Ponte, M, Mason, J, Helland, P, and Kim, N Paleonenvironments of the Nebraska Sand Hills. (1994). Society for Sedimentary Geology, Midcontinent Section, Field Trip Guidebook, University of Nebraska, Lincoln.Google Scholar
Tegen, I, Lacis, A.A, and Fung, I The influence on climate forcing of mineral aerosols from disturbed soils. Nature 380, (1996). 419 422.Google Scholar
Voelker, A.H.L, Grootes, P.M, Nadeau, M.-J, and Sarnthein, M Radiocarbon levels in the Iceland Sea from 25–53 kyr and their link to the Earth’s magnetic field intensity. Radiocarbon 42, (2000). 437 452.Google Scholar
Watts, W.A Vegetational history of the eastern United States 25,000 to 10,000 years ago. Wright, H.E Jr., Porter, S.C Late-Quaternary Environments of the United States Vol. 1, (1983). The Late Pleistocene (University of Minnesota Press, Minneapolis). 294 310.Google Scholar
Webb, T III, Cushing, E.J, Wright, H.E Jr. Holocene changes in the vegetation of the midwest. Wright, H.E Jr., Porter, S.C Late-Quaternary Environments of the United States Vol. 2, (1983). The Holocene (University of Minnesota Press, Minneapolis). 142 165.Google Scholar
Wells, P.V., Stewart, J.D., (1987). Spruce charcoal, conifer macrofossils, and landsnail and small-vertebrate faunas in Wisconsinan sediments on the High Plains of Kansas. In Johnson, W.C. Ed. Quaternary Environments of Kansas (Kansas Geological Survey Guidebook Series 5), pp. 129140.Google Scholar
Wintle, A.G, Shackleton, N.J, and Lautridou, J.P Thermoluminescence dating of periods of loess deposition and soil formation in Normandy. Nature 310, (1984). 491 493.Google Scholar
Wright, H.E Jr. Vegetation east of the Rocky Mountains 18,000 years ago. Quaternary Research 15, (1981). 113 125.Google Scholar