Hostname: page-component-848d4c4894-ndmmz Total loading time: 0 Render date: 2024-05-26T04:10:44.768Z Has data issue: false hasContentIssue false
  • English
  • Français

Loess transportation surfaces in west-central Wisconsin, USA

Published online by Cambridge University Press:  27 December 2023

Randall J. Schaetzl Open the ORCID record for Randall J. Schaetzl [Opens in a new window]
Randall J. Schaetzl*
Affiliation:
Department of Geography, Environment, and Spatial Sciences, Michigan State University, East Lansing, MI 48823, USA
*
Corresponding author: Randall J. Schaetzl, Email: soils@msu.edu
Get access Rights & Permissions [Opens in a new window]

Abstract

The concept of a loess transportation surface portends that saltating sands deflate silt/dust and send them into suspension. This process continues until a topographic barrier stops the saltating sand, allowing loess deposits to accumulate downwind. This paper reports on loess transportation surfaces in west-central Wisconsin, USA. During the postglacial period, cold, dry conditions coincided with strong northwesterly winds to initiate widespread saltation of freely available sands, deflating any preexisting loess deposits. Large parts of the study area are transportation surfaces, and lack loess. Loess deposits were only able to accumulate at “protected” sites—downwind from (east of) topographic barriers, such as isolated bedrock uplands and the north-to-south flowing Black River. Loess in locations from these barriers is thicker (sometimes >5 m) than would be expected, and in places has even accumulated above preexisting loess deposits. For example, downwind (east) of the Black River, most of the low-relief landscape is covered with ≈40–70 cm of silty loess, even though it is many tens of kilometers from the initial loess source. Upwind of the river, on the transportation surface, the low-relief landscape is only intermittently mantled with thin, scattered deposits of silty-sandy eolian sediment, and generally lacks loess.

Keywords

LoessEolian sandSaltationTransportation surfaceWind shadowSand rampPermafrost
Type
Research Article
Information
Quaternary Research , First View , pp. 1 - 17
Check for updates
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Quaternary Research Center

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

Amit, R., Enzel, Y., Mushkin, A., Gillespie, A., Batbaatar, J., Crouvi, O., Vandenberghe, J., An, Z., 2014. Linking coarse silt production in Asian sand deserts and Quaternary accretion of the Chinese Loess Plateau. Geology 42, 2326.CrossRefGoogle Scholar
Assallay, A.M., Rogers, C.D.F., Smalley, I.J., Jefferson, I.F., 1998. Silt: 2-62 um, 9-4 φ. Earth-Science Reviews 45, 6188.CrossRefGoogle Scholar
Attig, J.W., Bricknell, M., Carson, E.C., Clayton, L., Johnson, M.D., Mickelson, D.M., Syverson, K.M., 2011. Glaciation of Wisconsin. 4th ed. Wisconsin Geological and Natural History Survey Educational Series Publication 36. Wisconsin Geological and Natural History Survey, Madison.Google Scholar
Attig, J.W., Clayton, L., 1993. Stratigraphy and origin of an area of hummocky glacial topography, northern Wisconsin, U.S.A. Quaternary International 18, 6167.CrossRefGoogle Scholar
Attig, J.W., Muldoon, M.A., 1989. Pleistocene Geology of Marathon County, Wisconsin. Wisconsin Geological and Natural History Survey Information Circular 65. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Bagnold, R.A., 1941. The Physics of Blown Sand and Desert Dunes. Methuen, London.Google Scholar
Batchelor, C.J., Orland, I.J., Marcott, S.A., Slaughter, R., Edwards, R.L., Zhang, P., Li, X., Cheng, H., 2019. Distinct permafrost conditions across the last two glacial periods in midlatitude North America. Geophysical Research Letters 46, 1331813326.CrossRefGoogle Scholar
Bertran, P., Bosq, M., Boderie, Q., Coussot, C., Coutard, S., Deschodt, L., Franc, O., Gardere, P., Liard, M., Wuscher, P., 2021. Revised map of European aeolian deposits derived from soil texture data. Quaternary Science Reviews 266, 107085.CrossRefGoogle Scholar
Bettis, E.A. III, Muhs, D.R., Roberts, H.M., Wintle, A.G., 2003. Last glacial loess in the conterminous USA. Quaternary Science Reviews 22, 19071946.CrossRefGoogle Scholar
Bromwich, D.H., Toracinta, E.R., Wei, H., Oglesby, R.J., Fastook, J.L., Hughes, T.J., 2004. Polar MM5 simulations of the winter climate of the Laurentide Ice Sheet at the LGM. Journal of Climate 17, 34153433.2.0.CO;2>CrossRefGoogle Scholar
Cahow, A.C., 1976. Glacial Geomorphology of the Southwestern Segment of the Chippewa Lobe Moraine Complex, Wisconsin. PhD dissertation, Michigan State University, East Lansing.Google Scholar
Carson, E.C., Hanson, P.R., Attig, J.W., Young, A.R., 2012. Numeric control on the late-glacial chronology of the southern Laurentide Ice Sheet derived from ice-proximal lacustrine deposits. Quaternary Research 78, 583589.CrossRefGoogle Scholar
Clayton, L., 1991. Pleistocene Geology of Wood County, Wisconsin. Wisconsin Geological and Natural History Survey Information Circular 68. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Clayton, L., Attig, J.W., Mickelson, D.M., 2001. Effects of late Pleistocene permafrost on the landscape of Wisconsin, USA. Boreas 30, 173188.CrossRefGoogle Scholar
COHMAP Members, 1988. Climatic changes of the last 18,000 years: observations and model simulations. Science 241, 10431052.CrossRefGoogle Scholar
Conroy, J.L., Karamperidou, C., Grimley, D.A., Guenthe, W.R., 2019. Surface winds across eastern and midcontinental North America during the Last Glacial Maximum: a new data-model assessment. Quaternary Science Reviews 220, 1429.CrossRefGoogle Scholar
Demitroff, M., 2016. Pleistocene ventifacts and ice-marginal conditions, New Jersey, USA. Permafrost and Periglacial Processes 27, 123137.CrossRefGoogle Scholar
Faulkner, D.J., Larson, P.H., Jol, H.M., Running, G.L., Loope, H.M., Goble, R.J., 2016. Autogenic incision and terrace formation resulting from abrupt late-glacial base-level fall, lower Chippewa River, Wisconsin, USA. Geomorphology 266, 7595.CrossRefGoogle Scholar
Fehrenbacher, J.B., White, J.L., Ulrich, H.P., Odell, R.T., 1965. Loess distribution in southeastern Illinois and southwestern Indiana. Soil Science Society of America Proceedings 29, 566572.CrossRefGoogle Scholar
Frazee, C.J., Fehrenbacher, J.B., Krumbein, W.C., 1970. Loess distribution from a source. Soil Science Society of America Proceedings 34, 296301.CrossRefGoogle Scholar
French, H.M., Millar, S.W.S., 2014. Permafrost at the time of the Last Glacial Maximum (LGM) in North America. Boreas 43, 667677.CrossRefGoogle Scholar
Gardner, R.A.M., Rendell, H.M., 1994. Loess, climate and orogenesis: implications of South Asian loesses. Zeitschrift für Geomorphologie 2, 169184.CrossRefGoogle Scholar
Hallberg, G.R., 1979. Wind-aligned drainage in loess in Iowa. Proceedings of the Iowa Academy of Science 86, 49.Google Scholar
Hanson, P., Mason, J., Jacobs, P., Young, A., 2015. Evidence for bioturbation of luminescence signals in eolian sand on upland ridgetops, southeastern Minnesota, USA. Quaternary International 362, 108115.CrossRefGoogle Scholar
Hole, F.D., 1943. Correlation of the glacial border drift of north central Wisconsin. American Journal of Science 241, 498516.CrossRefGoogle Scholar
Hole, F.D., 1950 (repr. 1968). Aeolian Sand and Silt Deposits of Wisconsin. Wisconsin Geological and Natural History Survey Map. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Holmes, M.A., Syverson, K.M., 1997. Permafrost history of Eau Claire and Chippewa Counties, Wisconsin, as indicated by ice-wedge casts. The Compass 73, 9196.Google Scholar
Jacobs, P.M., Mason, J.A., Hanson, P.R., 2011. Mississippi Valley regional source of loess on the southern Green Bay Lobe land surface, Wisconsin. Quaternary Research 75, 574583.CrossRefGoogle Scholar
Jacobs, P.M., Mason, J.A., Hanson, P.R., 2012. Loess mantle spatial variability and soil horizonation, southern Wisconsin, USA. Quaternary International 265, 4253.CrossRefGoogle Scholar
Johnson, M.D., 1986. Pleistocene Geology of Barron County, Wisconsin. Wisconsin Geological and Natural History Survey Information Circular 55. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Johnson, M.D., 2000. Pleistocene Geology of Polk County, Wisconsin. Wisconsin Geological and Natural History Survey Bulletin 95. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Kasse, C., 1997. Cold-climate aeolian sand-sheet formation in North-Western Europe (c. 14–12.4 ka): a response to permafrost degradation and increased aridity. Permafrost and Periglacial Processes 8, 295311.3.0.CO;2-0>CrossRefGoogle Scholar
Kerr, P.J., 2023. A Late Wisconsin polygenetic landscape: connecting landforms on the Iowan erosion surface to past processes with LiDAR and field data. INQUA Conference, Rome, Italy, abstract.Google Scholar
Krist, F., Schaetzl, R.J., 2001. Paleowind (11,000 BP) directions derived from lake spits in northern Michigan. Geomorphology 38, 118.CrossRefGoogle Scholar
Kutzbach, J.E., Guetter, P.J., Behling, P.J., Selin, R., 1993. Simulated climatic changes: results of the COHMAP climate-model experiments. In: Wright, H.E. Jr., Kutzbach, J.E., Webb, T. III, Ruddiman, W.F., Street-Perrott, F.A., Bartlein, P.J. (Eds.), Global Climates since the Last Glacial Maximum. University of Minnesota Press, Minneapolis, pp. 2493.Google Scholar
Leigh, D.S., Knox, J.C., 1993. AMS radiocarbon age of the Upper Mississippi Valley Roxana Silt. Quaternary Research 39, 282289.CrossRefGoogle Scholar
Leighton, M.M., Willman, H.B., 1950. Loess formations of the Mississippi Valley. Journal of Geology 58, 599623.CrossRefGoogle Scholar
Li, Y., Shi, W., Aydin, A., Beroya-Eitner, M.A., Gao, G., 2020. Loess genesis and worldwide distribution. Earth-Science Reviews 201, 102947.CrossRefGoogle Scholar
Loope, W.L., Loope, H.M., Goble, R.J., Fisher, T.G., Lytle, D.E., Legg, R.J., Wysocki, D.A., Hanson, P.R., Young, A.R., 2012. Drought drove forest decline and dune building in eastern USA, as the upper Great Lakes became closed basins. Geology 40, 315318.CrossRefGoogle Scholar
Luehmann, M.D., Peter, B., Connallon, C.B., Schaetzl, R.J., Smidt, S.J., Liu, W., Kincare, K., Walkowiak, T.A., Thorlund, E., Holler, M.S., 2016. Loamy, two-storied soils on the outwash plains of southwestern Lower Michigan: pedoturbation of loess with the underlying sand. Annals of the American Association of Geographers 106, 551571.CrossRefGoogle Scholar
Luehmann, M.D., Schaetzl, R.J., Miller, B.A., Bigsby, M., 2013. Thin, pedoturbated and locally sourced loess in the western Upper Peninsula of Michigan. Aeolian Research 8, 85100.CrossRefGoogle Scholar
Mason, J.A., 2001. Transport direction of Peoria loess in Nebraska and implications for loess source areas on the central Great Plains. Quaternary Research 56, 7986.CrossRefGoogle Scholar
Mason, J.A., Jacobs, P.M., Leigh, D.S., 2019. Loess, eolian sand, and colluvium in the Driftless Area. Geological Society of America, Special Paper 543, 6173.Google Scholar
Mason, J.A., Nater, E.A., Bell, J.C., Hobbs, J.C., 1992. Use of ice-wedge casts to establish the relative age of soils and geomorphic surfaces in the Upper Midwest. Soil Science Society of America, Annual Meeting Abstracts.Google Scholar
Mason, J.A., Nater, E.A., Hobbs, H.C., 1994. Transport direction of Wisconsinan loess in southeastern Minnesota. Quaternary Research 41, 4451.CrossRefGoogle Scholar
Mason, J.A., Nater, E.A., Zanner, C.W., Bell, J.C., 1999. A new model of topographic effects on the distribution of loess. Geomorphology 28, 223236.CrossRefGoogle Scholar
Mason, J.A., Swinehart, J.B., Hanson, P.R., Loope, D.B., Goble, R.J., Miao, X., Schmeisser, R.L., 2011. Late Pleistocene dune activity in the central Great Plains, USA. Quaternary Science Reviews 30, 38583870.CrossRefGoogle Scholar
McSweeney, K., Leigh, D.S., Knox, J.C., Darmody, R.H., 1988. Micromorphological analysis of mixed zones associated with loess deposits of the midcontinental United States. In: Eden, D.N., Furkert, R.J. (Eds.), Loess: Its Distribution, Geology and Soils. Proceedings of an International Symposium, New Zealand, 13–21 February 1987. Balkema, Rotterdam, pp. 117130.Google Scholar
Miller, B.A., Schaetzl, R.J., 2012. Precision of soil particle size analysis using laser diffractometry. Soil Science Society of America Journal 76, 17191727.CrossRefGoogle Scholar
Mode, W.N., 1976. The Glacial Geology of a Portion of North-Central Wisconsin. M.S. thesis, University of Wisconsin–Madison.Google Scholar
Mudrey, M.G., Brown, B.A., Greenberg, J.K., 1982. Bedrock Geologic Map of Wisconsin. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Muhs, D.R., Bettis, E.A. III, 2000. Geochemical variations in Peoria loess of western Iowa indicate paleowinds of midcontinental North America during last glaciation. Quaternary Research 53, 4961.CrossRefGoogle Scholar
Muhs, D.R., Bettis, E.A. III, Roberts, H.M., Harlan, S.S., Paces, J.B., Reynolds, R.L., 2013. Chronology and provenance of last-glacial (Peoria) loess in western Iowa and paleoclimatic implications. Quaternary Research 80, 468481.CrossRefGoogle Scholar
Muhs, D.R., Bettis, E.A., Skipp, G.L., 2018. Geochemistry and mineralogy of late Quaternary loess in the upper Mississippi River valley, USA: provenance and correlation with Laurentide ice sheet history. Quaternary Science Reviews 187, 235269.CrossRefGoogle Scholar
Nickling, W.G., 1978. Eolian sediment transport during dust storms: Slims River Valley, Yukon Territory. Canadian Journal of Earth Sciences 15, 10691084.CrossRefGoogle Scholar
Nyland, K.E., Schaetzl, R.J., Ignatov, A., Miller, B.A., 2018. A new depositional model for sand-rich loess on the Buckley Flats outwash plain, northwestern Lower Michigan. Aeolian Research 31, 91104.CrossRefGoogle Scholar
Olson, C.G., Ruhe, R.V., 1979. Loess dispersion model, southwest Indiana, U.S.A. Acta Geologica Academiae Scientiarum Hungaricae, Tomus 22, 205227.Google Scholar
Pötter, S., Veres, D., Baykal, Y., Nett, J.J., Schulte, P., Hambach, U., Lehmkuhl, F., 2021. Disentangling sedimentary pathways for the Peniglacial Lower Danube Loess based on geochemical signatures. Frontiers in Earth Science 9, 600010.CrossRefGoogle Scholar
Putman, B.R., Jansen, I.J., Follmer, L.R., 1988. Loessial soils: their relationship to width of the source valley in Illinois. Soil Science 146, 241247.CrossRefGoogle Scholar
Roberts, H.M., Muhs, D.R., Wintle, A.G., Duller, G.A.T., Bettis, E.A. III, 2003. Unprecedented last-glacial mass accumulation rates determined by luminescence dating of loess from western Nebraska. Quaternary Research 59, 411419.CrossRefGoogle Scholar
Ruhe, R.V., 1973. Background of model for loess-derived soils in the upper Mississippi Valley. Soil Science 115, 250253.CrossRefGoogle Scholar
Ruhe, R.V., 1984. Loess derived soils, Mississippi valley region: I. Soil sedimentation system. Soil Science Society of America Journal 48, 859867.CrossRefGoogle Scholar
Rutledge, E.M., Holowaychuk, N., Hall, G.F., Wilding, L.P., 1975. Loess in Ohio in relation to several possible source areas: I. Physical and chemical properties. Soil Science Society of America Proceedings 39, 11251132.CrossRefGoogle Scholar
Schaetzl, R.J., Attig, J.W., 2013. The loess cover of northeastern Wisconsin. Quaternary Research 79, 199214.CrossRefGoogle Scholar
Schaetzl, R.J., Forman, S.L., Attig, J.W., 2014. Optical ages on loess derived from outwash surfaces constrain the advance of the Laurentide Ice Sheet out of the Lake Superior Basin, USA. Quaternary Research 81, 318329.CrossRefGoogle Scholar
Schaetzl, R.J., Hook, J., 2008. Characterizing the silty sediments of the Buckley Flats outwash plain: evidence for loess in NW Lower Michigan. Physical Geography 29, 1 18.CrossRefGoogle Scholar
Schaetzl, R.J., Krist, F.J. Jr., Luehmann, M.D. Lewis, C.F.M., Michalek, M.J., 2016. Spits formed in Glacial Lake Algonquin indicate strong easterly winds over the Laurentide Great Lakes during Late Pleistocene. Journal of Paleolimnology 55, 4965.CrossRefGoogle Scholar
Schaetzl, R.J., Larson, P.H., Faulkner, D.J., Running, G.L., Jol, H.M., Rittenour, T.M., 2018. Eolian sand and loess deposits indicate west-northwest paleowinds during the Late Pleistocene in Western Wisconsin, USA. Quaternary Research 89, 769785.CrossRefGoogle Scholar
Schaetzl, R.J., Luehmann, M.D., 2013. Coarse-textured basal zones in thin loess deposits: products of sediment mixing and/or paleoenvironmental change? Geoderma 192, 277285.CrossRefGoogle Scholar
Schaetzl, R.J., Nyland, K.E., Kasmerchak, C.S., Breeze, V., Kamoske, A., Thomas, S.E., Bomber, M., Grove, L., Komoto, K., Miller, B.A., 2021. Holocene, silty-sand loess immediately downwind of dunes in northern Michigan, USA. Physical Geography 42, 2529.CrossRefGoogle Scholar
Schaetzl, R.J., Running, G. IV, Larson, P., Rittenour, T., Yansa, C., Faulkner, D., 2022. Luminescence dating of sand wedges constrains the Late Wisconsin (MIS-2) permafrost interval in the Upper Midwest, USA. Boreas 51, 385401.CrossRefGoogle Scholar
Scull, P., Schaetzl, R.J., 2011. Using PCA to characterize and differentiate the character of loess deposits in Wisconsin and Upper Michigan, USA. Geomorphology 127, 143155.CrossRefGoogle Scholar
Shandonay, K.L., Bowen, M.W., Larson, P.H., Running, G.L., Rittenour, T., Mataitis, R., 2022. Morphology and stratigraphy of aeolian sand stringers in southeast Minnesota and western Wisconsin, USA. Earth Surface Processes and Landforms 47, 28632876.CrossRefGoogle Scholar
Smalley, I.J., 1966. The properties of glacial loess and the formation of loess deposits. Journal of Sedimentary Petrology 36, 669676.CrossRefGoogle Scholar
Smalley, I.J., Vita Finzi, C., 1968. The formation of fine particles in sandy deserts and the nature of “desert” loess. Journal of Sedimentary Petrology 38, 766 774.Google Scholar
Smith, B.J., Wright, J.S., Whalley, W.B., 2002. Sources of non-glacial, loess-size quartz silt and the origins of “desert loess.” Earth-Science Reviews 59, 126.CrossRefGoogle Scholar
Smith, G.D., 1942. Illinois Loess: Variations in Its Properties and Distribution. University of Illinois Agricultural Experiment Station, Bulletin 490. University of Illinois, Agricultural Experiment Station, Urbana-Champaign.Google Scholar
Stevens, T., Sechi, D., Tziavaras, C., Schneider, R., Banak, A., Andreucci, S., Hattestrand, M., Pascucci, V., 2022. Age, formation and significance of loess deposits in central Sweden. Earth Surface Processes and Landforms 47, 32763301.CrossRefGoogle Scholar
Stewart, M.T., 1973. Pre-Woodfordian Drifts of North-Central Wisconsin. M.S. thesis, University of Wisconsin–Madison.Google Scholar
Stewart, M.T., Mickelson, D.M., 1976. Clay mineralogy and relative ages of tills in north-central Wisconsin. Journal of Sedimentary Petrology 46, 200205.Google Scholar
Sweeney, M.R., Busacca, A.J., Gaylord, D.R., Gaylord, A., 2005. Topographic and climatic influences on accelerated loess accumulation since the last glacial maximum in the Palouse, Pacific Northwest, USA. Quaternary Research 63, 261273.CrossRefGoogle Scholar
Sweeney, M.R., Mason, J.A., 2013. Mechanisms of dust emission from Pleistocene loess deposits, Nebraska, USA. Journal of Geophysical Research: Earth Surface 118, 14601471.CrossRefGoogle Scholar
Syverson, K.M., 2007. Pleistocene Geology of Chippewa County, Wisconsin. Wisconsin Geological and Natural History Survey Bulletin 103. University of Wisconsin-Extension, Geological and Natural History Survey, Madison.Google Scholar
Syverson, K.M., Colgan, P.M., 2011. The Quaternary of Wisconsin: an updated review of stratigraphy, glacial history, and landforms. In: Ehlers, J., Gibbard, P.L., Hughes, P.D. (Eds.), Quaternary Glaciations—Extent and Chronology. Part IV, A Closer Look. Elsevier, Amsterdam, pp. 537552.CrossRefGoogle Scholar
Thomas, D.D., 1977. Soil Survey of Eau Claire County, Wisconsin. Soil Conservation Service, U.S. Government Printing Office, Washington, DC.Google Scholar
Van Huissteden, J.K., Vandenberghe, J., Van der Hammen, T., Laan, W., 2000. Fluvial and aeolian interaction under permafrost conditions: Weischselian Late Pleniglacial, Twente, eastern Netherlands. Catena 40, 307321.CrossRefGoogle Scholar
Vanmaercke-Gottigny, M.C., 1981. Some geomorphological implications of the cryo-aeolian deposits in western Belgium. Biuletyn periglacial 28, 103114.Google Scholar
Walters, J.C., 1994. Ice-wedge casts and relict polygonal ground in north-east Iowa, USA. Permafrost and Periglacial Processes 5, 269282.CrossRefGoogle Scholar
Wang, Z.Y., Wu, Y.Q., Li, D.W., Fu, T.Y., 2022. The southern boundary of the Mu Su Sand Sea and its controlling factors. Geomorphology 396, 108010.CrossRefGoogle Scholar
Waroszewski, J., Sprafke, T., Kabala, C., Kobierski, M., Kierczak, J., Musztyfaga, E., Loba, A., Mazurek, R., Labaz, B., 2019. Tracking textural, mineralogical and geochemical signatures in soils developed from basalt-derived materials covered with loess sediments (SW Poland). Geoderma 337, 983997.CrossRefGoogle Scholar
Waroszewski, J., Sprafke, T., Kabala, C., Musztyfaga, E., Łabaz, B., 2017. Aeolian silt contribution to soils on mountain slopes (Mt. Ślęża, SW Poland). Quaternary Research 89, 116.Google Scholar