Hostname: page-component-586b7cd67f-gb8f7 Total loading time: 0 Render date: 2024-11-23T19:36:46.127Z Has data issue: false hasContentIssue false

Loess transportation surfaces in west-central Wisconsin, USA

Published online by Cambridge University Press:  27 December 2023

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: [email protected]
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.

Type
Research Article
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Quaternary Research Center

INTRODUCTION

To develop loess deposits, a mechanism must first exist to form silt. Commonly, glacial grinding and eolian abrasion are assumed to be the most effective processes for silt production/generation (Smalley, Reference Smalley1966; Smalley and Vita Finzi, Reference Smalley and Vita Finzi1968; Gardner and Rendell, Reference Gardner and Rendell1994; Assallay et al., Reference Assallay, Rogers, Smalley and Jefferson1998; Smith et al., Reference Smith, Wright and Whalley2002). That said, eolian abrasion has also been invoked as a mechanism of silt generation, for example, Amit et al. (Reference Amit, Enzel, Mushkin, Gillespie, Batbaatar, Crouvi, Vandenberghe and An2014). Next, the silt must be entrained/deflated from its resting place and brought into atmospheric suspension. Silt and dust in suspension are then subject to transportation processes and, finally, deposition as loess. Deflation, transportation, deposition—all of Earth's loess deposits have experienced these three processes, usually in this order, and sometimes more than once. This paper expands on this loess generation “pathway” for sites in Wisconsin, USA, although the findings are potentially applicable to loess in a variety of environments.

In a now-classic paper, Mason et al. (Reference Mason, Nater, Zanner and Bell1999) demonstrated how topography can have a dramatic effect on the transportation and (eventual) distribution of silt/dust, both regionally and locally (Fig. 1). They defined a loess transportation surface as a landscape where saltating sand can assist in the deflation/mobilization of silt grains, as initially discussed by Bagnold (Reference Bagnold1941) and as observed by Nickling (Reference Nickling1978), thereby facilitating the transportation of fine-grained dust particles. Very little loess is actually retained on such a transportation surface, as the saltating sand is so effective at (further) mobilizing any silt that may have been temporarily deposited there. Important to the efficacy of a loess transportation surface is its “sparsely vegetated” character; well-vegetated surfaces would act to protect silt from the impacts of saltating sand. According to the model, silt and dust that have been mobilized (or remobilized) by saltating sand will stay episodically in transit until some sort of topographic obstacle/barrier is encountered, which stops/traps the saltating sand but allows the silt to continue on, downwind, in suspension. Such obstacles or barriers may be deep valleys or high uplands, for example, Sweeney et al. (Reference Sweeney, Busacca, Gaylord and Gaylord2005). As a result, relatively sand-poor deposits of loess often accumulate downwind of topographic obstacles. I acknowledge that silt can be deflated without the assistance of saltating sand, for example, Sweeney and Mason (Reference Sweeney and Mason2013), but if sand is present, the process may be more robust.

Figure 1. A reproduction of fig. 4 in the loess transportation surface paper by Mason et al. (Reference Mason, Nater, Zanner and Bell1999).

The loess transportation surface model (LTSM, my nomenclature) was a game-changer for geoscientists working on landscapes where loess deposits are variable in thickness and texture and where sand is freely available. It provided the theoretical framework necessary to explain why some areas lack loess, while areas in close proximity have thick deposits of loess, and why the boundary between the two can be very abrupt (such as a deep river valley or a high, narrow ridge). Its utility is worldwide and it continues to be a highly useful explanatory model for loess distributions at all scales (Vanmaercke-Gottigny, Reference Vanmaercke-Gottigny1981; Sweeney et al., Reference Sweeney, Busacca, Gaylord and Gaylord2005; Nyland et al., Reference Nyland, Schaetzl, Ignatov and Miller2018; Mason et al., Reference Mason, Jacobs and Leigh2019; Li et al., Reference Li, Shi, Aydin, Beroya-Eitner and Gao2020; Bertran et al., Reference Bertran, Bosq, Boderie, Coussot, Coutard, Deschodt, Franc, Gardere, Liard and Wuscher2021; Pötter et al., Reference Pötter, Veres, Baykal, Nett, Schulte, Hambach and Lehmkuhl2021; Schaetzl et al., Reference Schaetzl, Nyland, Kasmerchak, Breeze, Kamoske, Thomas, Bomber, Grove, Komoto and Miller2021; Stevens et al., Reference Stevens, Sechi, Tziavaras, Schneider, Banak, Andreucci, Hattestrand and Pascucci2022; Wang et al., Reference Wang, Wu, Li and Fu2022), and even for dune sand (Loope et al., Reference Loope, Loope, Goble, Fisher, Lytle, Legg, Wysocki, Hanson and Young2012; Shandonay et al., Reference Shandonay, Bowen, Larson, Running, Rittenour and Mataitis2022; Wang et al., Reference Wang, Wu, Li and Fu2022).

The purpose of this paper is to provide data-rich, clear-cut examples of how the LTSM explains not only loess distributions across a landscape, but also loess textures and thicknesses. I do not intend this research to be so much an affirmation of the LTSM, or even a test. Rather, my approach is to use an extensive data set of loess thicknesses and textures, across and downwind of a transportation surface, to add theoretical depth and detail to the model. The data derive from a landscape of variable (but generally low) relief in west-central Wisconsin, USA, where sands are freely available, where loess sources are generally known, and where postglacial transport directions were fairly uniform. Thus, data from this landscape provide an excellent application of the LTSM, which may add to our understanding of loess deflation–transportation–deposition systems worldwide.

STUDY AREA

Most of the study area in west-central Wisconsin lies within Chippewa and Eau Claire Counties on the west, and Clark County on the east. Although this landscape is generally low relief, it nonetheless has some isolated hills of sandstone that rise sometimes as high as 40–60 m above the surrounding landscape.

Glacial sediments and history

As indicated by the Late Wisconsin terminal moraine, which spans the northern margins of the study area, only the northern part of the study area was glaciated during Marine Oxygen Isotope Stage 2 (MIS 2; Attig et al., Reference Attig, Bricknell, Carson, Clayton, Johnson, Mickelson and Syverson2011; Syverson and Colgan, Reference Syverson, Colgan, Ehlers, Gibbard and Hughes2011; Fig. 2). Earlier glaciers did, however, advance as far south as southeastern Chippewa County, and into northern and central Clark County and nearby areas (Hole, Reference Hole1943; Clayton, Reference Clayton1991; Syverson, Reference Syverson2007). Sediment associated with the earliest of these glaciers, mapped within the Bakerville Member of the River Falls Formation, is found mainly in southern Clark County (Syverson and Colgan, Reference Syverson, Colgan, Ehlers, Gibbard and Hughes2011). Ice that deposited this sediment flowed south, out of the Lake Superior basin, leaving behind reddish-brown, sandy loam till that, in places, drapes sandstone uplands. Bakerville tills average 57–63% sand (Mode, Reference Mode1976; Attig and Muldoon, Reference Attig and Muldoon1989; Syverson, Reference Syverson2007). The age of this glacial advance has not been confirmed, but may date to MIS 6 or 8 (Syverson and Colgan, Reference Syverson, Colgan, Ehlers, Gibbard and Hughes2011).

Figure 2. The regional setting for this study—northern Wisconsin, USA—showing the extent of Marine Oxygen Isotope Stage 2 (MIS 2; Late Wisconsin) glaciation, the major rivers that drain to the south across the region, and some county names.

Evidence for an Early Wisconsin, possibly MIS 4, glaciation in the study area exists as sediment within the Merrill Member of the Copper Falls Formation, south of the Late Wisconsin moraine. Stewart and Mickelson (Reference Stewart and Mickelson1976) reported a 14C date on organic material overlying this till that suggested an Early Wisconsin age. Tills of the Merrill Member are loam and sandy loam in texture, averaging 49–63% sand (Stewart, Reference Stewart1973; Attig and Muldoon, Reference Attig and Muldoon1989; Mode, Reference Mode1976; Syverson, Reference Syverson2007).

Late Wisconsin (MIS 2) ice was the last glacial advance into the study area, where it formed a wide, conspicuous, and hummocky end moraine (Attig and Clayton, Reference Attig and Clayton1993; Syverson and Colgan, Reference Syverson, Colgan, Ehlers, Gibbard and Hughes2011; Fig. 2). At this time, meltwater formed valley trains of sandy and gravelly outwash. Permafrost had developed on landscapes within ≈100 km of the ice margin and persisted, between ≈19 and 15 ka (Holmes and Syverson, Reference Holmes and Syverson1997; Schaetzl et al., Reference Schaetzl, Running, Larson, Rittenour, Yansa and Faulkner2022). Sand wedges that formed during this interval point to dry, cold, windy conditions across the study area. Ventifacts and bouldery surface lag deposits, which are common on these same landscapes, also support the notion of cold, windy, erosive conditions across the study area during and after the Late Wisconsin advance (Johnson, Reference Johnson1986; Syverson, Reference Syverson2007; Schaetzl et al., Reference Schaetzl, Larson, Faulkner, Running, Jol and Rittenour2018).

Eolian sediments and history

Across the study area, as well as to its west (upwind), sandy sediments are widespread. Three main sources of sand exist here: (1) isolated uplands of sandstone bedrock, most of which is quite friable and easily weathered and eroded (Mudrey et al., Reference Mudrey, Brown and Greenberg1982); (2) glacial sediments south of the Late Wisconsin moraine, which only shallowly overlie sandstone in many locations (Fig. 2); and (3) glacial outwash, sourced from the Late Wisconsin ice sheet and carried south, through the study area, by meltwater streams. The largest valley train deposits of this kind are associated with the Chippewa River, which has several high, wide alluvial terraces formed in outwash (Faulkner et al., Reference Faulkner, Larson, Jol, Running, Loope and Goble2016). Other, smaller streams also carried outwash, most notably the Eau Claire and Black Rivers.

Broadly speaking, loess deposits in Wisconsin and the Upper Great Lakes region are very spatially variable both in thickness and in texture (Hole, Reference Hole1950; Scull and Schaetzl, Reference Scull and Schaetzl2011; Jacobs et al., Reference Jacobs, Mason and Hanson2012; Schaetzl and Attig, Reference Schaetzl and Attig2013). Many areas of the state lack loess entirely, usually because they were below a glacial lake (or the glacier) or on an aggrading outwash surface during the main loess depositional interval. Other loess-free areas occur on steep slopes, and thus any prexisting loess cover has been removed by erosion, or (as is most applicable here) are on landscapes where (presumably) saltating sand has deflated any preexisting loess. Interestingly, many of these loess-free areas immediately abut areas with thick loess (Fig. 3). Explaining the great spatial variability in the loess cover—at any of a variety of scales—has been a challenge for decades and was an impetus for this study.

Figure 3. Loess deposits within the study area, as interpreted from the various county soil surveys of the Natural Resources Conservation Service (U.S. Department of Agriculture). Colors correspond to loess thicknesses. Gray areas, showing only the underlying hillshade digital elevation model (DEM), indicate areas that, according to the soil maps, lack a loess cover. As defined here, the extent of the loess transportation surface is shown, broadly, by diagonal lines. The inset box shows the extent of the landscape in this figure, on a small-scale map of the state of Wisconsin.

Most of the loess in Wisconsin was derived from outwash surfaces (outwash plains and valley trains) and glacial lake plains formed during MIS 2, when the Laurentide Ice Sheet was retreating from the Upper Great Lakes region. Early researchers realized that this loess had generally been transported from west to east, as evidenced by the great thickness of loess deposits on the bluffs immediately east of the Mississippi River and other major, north-to-south flowing rivers (Hole, Reference Hole1950; Ruhe, Reference Ruhe1984; Bettis et al., Reference Bettis, Muhs, Roberts and Wintle2003; Muhs et al., Reference Muhs, Bettis and Skipp2018). Spatial data on loess thickness and texture in southeastern Minnesota, just west of the study area, also indicate west-to-east transport of loess (Mason et al., Reference Mason, Nater and Hobbs1994). Loess sources to the west of the Mississippi River floodplain were also important. For example, on uplands farther west, some of the preexisting loess was deflated and transported to Wisconsin (Mason et al., Reference Mason, Nater and Hobbs1994; Jacobs et al., Reference Jacobs, Mason and Hanson2011; Schaetzl et al., Reference Schaetzl, Larson, Faulkner, Running, Jol and Rittenour2018).

I delimited the major loess transportation surface in the study area based on its general lack of loess cover (Fig. 3). Sands are common both on and upwind of the transportation surface (Fig. 4). Low uplands on the otherwise low-relief transportation surface are typically mantled with till, bedrock residuum, or a thin cover of loamy sand- and sand-textured sediment that have an eolian history. And, as expected on a loess transportation surface, loess occurs in downwind areas, immediately beyond major topographic obstructions—in this case, best exemplified by the Black River valley (Fig. 3). The remainder of this paper explains in more detail the evidence for this area as a loess transportation surface and its impact on loess textures and distributions.

Figure 4. The extent of loess, glacial outwash, and sands within the study area and in areas farther west. Loess thickness symbology follows that in Fig. 3. Data derive from NRCS soil surveys.

MATERIALS AND METHODS

Hole's (Reference Hole1950) map of eolian silt and sand deposits first identified—fairly accurately, given the scale of the map—the patchy nature of the loess across the study area. Additional detail on loess thickness and distribution was provided from Natural Resources Conservation Service (NRCS) county soil maps (Fig. 3). Data from these maps were downloaded from the NRCS's SSURGO/STATSGO2 Metadata site (https://www.nrcs.usda.gov/resources/data-and-reports/ssurgo/stats2go-metadata) and imported into a GIS. In the GIS, I rasterized the initial vector files and seamed the various coverages together into a raster mosaic. Using this data set, I next determined the parent material(s) for most of the soil series from the official series descriptions (OSDs) on the NRCS website (https://www.nrcs.usda.gov/resources/data-and-reports/official-soil-series-descriptions-osd). When the parent material description for a soil series was stated to be loess, usually over another sediment (or bedrock), loess thickness was gleaned from the OSD and entered into the GIS attribute table, using these thickness categories:

  • Loess > 152 cm (> 60 inches)

  • Loess = 102–152 cm (40–60 inches)

  • Loess = 51–102 cm (20–40 inches)

  • Loess = 25–51 cm (10–20 inches), and

  • Loess absent or < 25 cm (< 10 inches)

The data were then loaded onto a laptop computer equipped with a built-in GPS unit, thus facilitating field navigation to predetermined sites for sampling. Figure 3 provides the color legend used on these maps.

The first sampling goal was to obtain a large number of representative samples of eolian sediment from broad upland sites of low slope gradient, where loess was mapped, using a repeatable and consistent methodology. Stable, upland sites would have been most likely to retain loess by limiting erosion, redistribution, and/or burial. A digital elevation model (DEM) with 10 m resolution, used in conjunction with the soils data, helped to optimize potential sample targets. Forested areas were best, because they typically have never been plowed; agricultural fields were lower priority but were, necessarily, sampled in some areas.

Across the assumed loess transportation surface (Fig. 3), the goal was to obtain samples of whatever eolian sediment may exist on broad, stable uplands, where it would most likely have been preserved. After these types of sites were visited, samples were taken only if the sediment exhibited clear “eolian characteristics,” such as the lack of coarse fragments and minimal amounts of coarse and very coarse sand; key to this identification, however, was the well-sorted nature of the sediment. Vegetation cover helped identify sites with an eolian mantle; sites that lacked such a cover were often in oak forest, being too sandy and coarse-textured for agriculture. Sites with a mantle of eolian sediment typically had a more mesic forest cover or were in cultivation. Almost always, below the lithologic contact between the eolian sediment (whether in the loess areas or on the transportation surface), the amount of coarser sands and gravels increased, making the field determinations relatively straightforward. At sites on stable uplands within the loess transportation surface where eolian sediment was not present, the site was noted in the GIS as such.

Spatially, the goal was for a relatively uniform sample grid. In areas of fairly uniform loess coverage, such as the loess-covered landscape east of the Black River (Fig. 3), the goal was for a sample density of one sample every ≈18–20 km2. Nonetheless, in areas where loess thicknesses and textures changed rapidly over short distances, sample densities were much greater. For example, I sampled at high densities the thick loess that occurs to the east-southeast of several large sandstone uplands in the western part of the study area (Schaetzl et al., Reference Schaetzl, Larson, Faulkner, Running, Jol and Rittenour2018).

In the field, at each of the several hundred sample sites, the thickness of the (presumed) eolian sediment was first determined in the field with a shovel and/or by hand auger. If the sediment was determined to be eolian in origin, a 500–600 g sample was then recovered and the thickness recorded. Because this work was performed mainly with a 195-cm-long hand auger, any site where the eolian sediment is thicker than 195 cm was recorded as 195 cm in the GIS. Because all sampling sites were located on stable uplands, all thicknesses should be viewed as maximum values; eolian sediment there would have experienced minimal erosion, as compared with adjacent, more sloping sites. The field-sampling goal was to obtain an amalgamated sample of eolian sediment that was representative of its entire thickness, while avoiding sampling the loess immediately above the underlying lithologic discontinuity. Loess and thin eolian deposits are often mixed with underlying sediment, especially in areas known to have had permafrost (McSweeney et al., Reference McSweeney, Leigh, Knox, Darmody, Eden and Furkert1988; Luehmann et al., Reference Luehmann, Schaetzl, Miller and Bigsby2013, Reference Luehmann, Peter, Connallon, Schaetzl, Smidt, Liu, Kincare, Walkowiak, Thorlund and Holler2016; Schaetzl and Attig, Reference Schaetzl and Attig2013; Schaetzl and Luehmann, Reference Schaetzl and Luehmann2013; Waroszewski et al., Reference Waroszewski, Sprafke, Kabala, Musztyfaga and Łabaz2017, Reference Waroszewski, Sprafke, Kabala, Kobierski, Kierczak, Musztyfaga, Loba, Mazurek and Labaz2019). Thus, great care was taken to avoid sampling these mixed zones. Areas of obvious disturbance, for example, tree uprooting, were also avoided.

All samples were taken back to the laboratory, air-dried, lightly ground to pass a 2 mm sieve, and passed through a sample splitter two times, in order to achieve the homogeneity necessary for laser particle size diffraction on a Malvern Mastersizer 2000. From each loess sample, a small subsample was dispersed in a water-based solution of (NaPO3)13⋅Na2O, after shaking for 10–15 min. As discussed in Miller and Schaetzl (Reference Miller and Schaetzl2012), small subsamples analyzed in laser particle size analyzers are not always representative. Thus, I analyzed two subsamples from each sample and compared the data numerically. In cases where the suite of particle size data were sufficiently similar, I used the mean values for all subsequent data analyses. When the data from the two runs were sufficiently dissimilar (see Miller and Schaetzl [Reference Miller and Schaetzl2012] for details), a third, or sometimes a fourth or fifth, subsample was run, and the two most comparable samples were used to generate the mean values used in subsequent analyses.

Finally, because of the assumed importance of sand and westerly winds on the transportation surface, I derived sand data from ≈2 kg samples taken from 17 sites across the region. These sites were (1) a gravel pit in the outwash deposits of the Chippewa River, (2) the sandy alluvium of the Eau Claire River valley, and (3) an upland on the transportation surface where the sediment was unmistakably eolian sand. After each sample was fully homogenized in the lab, I subsampled it and counted sand grains, forming two groups: (1) quartz and chert and (2) all others. The goal behind this grain-counting strategy was to generally differentiate light from heavy minerals within the sands.

RESULTS AND DISCUSSION

Much of the loess transportation surface identified in Figure 3 lacks a cover of eolian sediment of any kind, and where eolian sediment does occur, it is thin and patchy. Explaining this distribution, through application of the LTSM, is a goal of this paper. The LTSM requires that sand is available to deflate silt grains, and, of course, wind must also be strong enough to transport the sand. Finally, vegetation cover must be minimal enough that sand is exposed, making the land surface vulnerable to deflation. All of these preconditions exist (or once existed) within the loess transportation surface, as delineated in Figure 3.

Eolian transport directions and intensity

MIS 2 loess (Peoria Silt) is widespread across the upper Midwest and Great Plains of the United States (Bettis et al., Reference Bettis, Muhs, Roberts and Wintle2003). Although most of the thick Peoria loess deposits are south of the study area, the same sediment can be traced up and into the study area, where it drapes uplands on both sides of the Mississippi River valley. Peoria Loess covers many areas that were also glaciated during MIS 2, implying that its deposition continued past the LGM (last glacial maximum) period, for example, Schaetzl and Hook (Reference Schaetzl and Hook2008) and Jacobs et al. (Reference Jacobs, Mason and Hanson2011).

Early researchers understood that loess deposits across the upper Midwest, most of which are associated with glacial meltwater, had been generally transported on westerly winds, based on spatial patterns of thickness and texture (Smith, Reference Smith1942; Leighton and Willman, Reference Leighton and Willman1950; Fehrenbacher et al., Reference Fehrenbacher, White, Ulrich and Odell1965; Frazee et al., Reference Frazee, Fehrenbacher and Krumbein1970; Ruhe, Reference Ruhe1973; Rutledge et al., Reference Rutledge, Holowaychuk, Hall and Wilding1975; Hallberg, Reference Hallberg1979; Olson and Ruhe, Reference Olson and Ruhe1979; Putman et al., Reference Putman, Jansen and Follmer1988; Mason et al., Reference Mason, Nater and Hobbs1994). Both model data (COHMAP Members, 1988; Kutzbach et al., Reference Kutzbach, Guetter, Behling, Selin, Wright, Kutzbach, Webb, Ruddiman, Street-Perrott and Bartlein1993; Conroy et al., Reference Conroy, Karamperidou, Grimley and Guenthe2019), as well as more recent work on eolian deposits (Muhs and Bettis, Reference Muhs and Bettis2000; Mason, Reference Mason2001; Bettis et al., Reference Bettis, Muhs, Roberts and Wintle2003; Roberts et al., Reference Roberts, Muhs, Wintle, Duller and Bettis2003; Mason et al., Reference Mason, Swinehart, Hanson, Loope, Goble, Miao and Schmeisser2011; Muhs et al., Reference Muhs, Bettis, Roberts, Harlan, Paces and Reynolds2013, 2018), have continued to support these early interpretations, while adding detail to knowledge of regional paleocirculation patterns. Exceptions occur, however, where evidence suggests an easterly paleowind component, although these instances are typically more “local” and are ascribed either to passing cyclones (Muhs and Bettis, Reference Muhs and Bettis2000) or to katabatic winds off the ice sheet (Krist and Schaetzl, Reference Krist and Schaetzl2001; Schaetzl and Attig, Reference Schaetzl and Attig2013; Schaetzl et al., Reference Schaetzl, Krist, Luehmann, Lewis and Michalek2016). That is, a broadscale, regional pattern of westerly winds at and near the LGM remains widely accepted for the study area.

Paleoclimate data for the study area in Wisconsin during and immediately after the LGM add even more detail to this overall picture. Modeled data indicate dry, cold conditions at the LGM (Bromwich et al., Reference Bromwich, Toracinta, Wei, Oglesby, Fastook and Hughes2004), which is consistent with ground data showing permafrost at this time (Holmes and Syverson, Reference Holmes and Syverson1997; Johnson, Reference Johnson1986; Clayton et al., Reference Clayton, Attig and Mickelson2001; French and Millar, Reference French and Millar2014; Batchelor et al., Reference Batchelor, Orland, Marcott, Slaughter, Edwards, Zhang, Li and Cheng2019; Schaetzl et al., Reference Schaetzl, Running, Larson, Rittenour, Yansa and Faulkner2022). Winter was the windiest season (Bromwich et al., Reference Bromwich, Toracinta, Wei, Oglesby, Fastook and Hughes2004).

In the following sections, I discuss two ways in which loess transportation surfaces may have functioned in the region: (1) short-distance transport up and over isolated bedrock knobs, associated with sand ramps; and (2) long-distance transport across low-relief surfaces. Both cases illustrate the utility of the model of Mason et al. (Reference Mason, Nater, Zanner and Bell1999), explaining why loess deposition is often focused in areas downwind of a topographic obstruction.

Loess transportation systems I: the role of isolated, bedrock uplands

Within the study area, as in Iowa (Kerr, Reference Kerr2023), a variety of data are in strong agreement for postglacial eolian transport along a focused, west-northwest direction (Schaetzl et al., Reference Schaetzl, Larson, Faulkner, Running, Jol and Rittenour2018). For example, long, narrow, sand stringers—not unlike small longitudinal dunes—on sandy surfaces to the immediate west of the study area, which have been interpreted as age-equivalent to loess, are nicely aligned WNW-ESE (Schaetzl et al., Reference Schaetzl, Nyland, Kasmerchak, Breeze, Kamoske, Thomas, Bomber, Grove, Komoto and Miller2021; Shandonay et al., Reference Shandonay, Bowen, Larson, Running, Rittenour and Mataitis2022). Sand ramps are also common on the western sides of bedrock uplands (Hanson et al., Reference Hanson, Mason, Jacobs and Young2015; Schaetzl et al., Reference Schaetzl, Nyland, Kasmerchak, Breeze, Kamoske, Thomas, Bomber, Grove, Komoto and Miller2021; Shandonay et al., Reference Shandonay, Bowen, Larson, Running, Rittenour and Mataitis2022). The fairly uniform loess cover on the bedrock uplands in the far western parts of the study area adds to the interpretation of west-to-east transport of eolian siltloes. The loess is thickest and coarsest near the Mississippi River valley (a silt source). Although the loess thins gradually to the east, it uniformly covers the flat, table-like uplands near the river. Importantly though, this loess cover then becomes (locally) much thicker just east of the steep, bedrock escarpments that mark the eastern edge of the upland, as if the loess were preferentially accumulating in the "wind shadow" of the escarpment (Fig. 5).

Figure 5. Maps of loess sample locations, symbolized by thickness categories, across western Wisconsin. Inset maps show detail for selected areas.

However, the most convincing primary data that support the WNW-to-ESE transport of eolian sediment lies in the local distribution of loess deposits, relative to high, isolated bedrock knobs. Across the study area, loess is routinely absent on the west and northwest slopes of these ridges. Here, bedrock is often at the surface or covered by thin deposits of poorly sorted, sandy-silty regolith (Fig. 6A) or by sand ramps of well-sorted eolian sand. Thick loess occurs, however, on the east and southeast sides of these same ridges (Fig. 6B and C), and for some distance out and onto the lowlands beyond. The boundary between the area of nonexistent (or very thin) loess on the W-NW slopes versus the E-SE slopes is often very abrupt, and usually closely follows the ridgetop crest. (For the purposes of discussion, the W-NW slopes will hereafter be referred to as the windward slopes, and the E-SE slopes as the lee slopes.) This pattern is repeated on almost all of the isolated uplands in the region. Indeed, within the transportation surface landscape, loess usually only occurs (1) as scattered, thin deposits on the low-relief lowlands; and (2) in “protected” areas, such as in footslopes at the bottoms of narrow coves and ravines. The site shown in Figure 7 is a typical example of this relationship. Ridgetops in the study area are often mapped within the Northfield soil series, a Lithic Hapludalf that is described in the county soil survey as having bedrock at 41 cm (Thomas, Reference Thomas1977). Sideslopes and footslopes on the windward sides of the ridges are often mapped within the Elkmound soil series, a Typic Dystrudept whose offical series description also lists bedrock at 41 cm. Fieldwork in this area has repeatedly confirmed this relationship. At a number of sites along the windward slope of the ridge shown in Figure 7, field reconnaissance indicated thick deposits of eolian sand in coves and on toeslopes, but the backslopes were covered with only ca. 20–70 cm of loamy sediment overlying sandstone. I interpret these windward slopes as loess transportation surfaces, or sand ramps, incapable of retaining loess while winds were strong. Nonetheless, thick deposits of better-sorted, eolian sand were deposited and retained in protected areas at the bases of the slopes. Lower, smaller ridges, like the one in the southwest part of the landscape shown in Figure 7, were unable to “protect” lee sites, and hence they lack loess on all sides.

Figure 6. Exposures of rock and sediment on the windward and lee sides of a sandstone upland in the study area. (A) A thin veneer of regolith mantles sandstone bedrock on the windward side of the ridge. (B) Loess > 5 m thick is exposed at the Geist core site, in the immediate lee of the bedrock ridge (see Fig. 9). Shovel for scale. (C) Row-crop agriculture flourishes in the thick loess that lies in the lee of the bedrock ridges in the distance. Photos by the author.

Figure 7. Topography, soils, and loess cover on and near a small, isolated, sandstone ridge (and a smaller, neighboring ridge) in the west-central study area. Soils data from NRCS soil maps.

As shown in Figures 6 and 7, loess across the transportation surface is most common, and thickest, on the east and southeast sides of isolated bedrock knobs (Schaetzl et al., Reference Schaetzl, Larson, Faulkner, Running, Jol and Rittenour2018). Indeed, field data across the study area indicate that sites with loess thicknesses >195 cm occur in only two types of locations: (1) on flat, stable ridgetops immediately downwind of the Mississippi River valley (an immediate loess source); and (2) in the lee of bedrock ridges (Fig. 5). Areas between the bedrock knobs are usually sandy and low relief, lacking loess entirely (Fig. 5). This pattern can be explained in two ways, both of which seem plausible; both follow the LSTM.

Scenario 1

In this scenario, during the main Peoria loess deposition interval, eolian silt being transported in from western sources was only able to accumulate on the sheltered, lee sides of ridges, because these same westerly winds generated clouds of saltating sand, deflated from outwash surfaces, exposed sandstone uplands, and sandy tills. This sand, transported up and around the windward slopes of bedrock knobs, helped mobilize the silt, preventing it from accumulating in all but the most topographically protected sites. Saltation would have ceased at the ridgetops, allowing loess (and some of the finest sands) to accumulate on their lee slopes and on lower relief sites downwind (Fig. 7). Thick deposits of eolian sand sometimes also accumulated in topographically preferred (protected) windward sites on bedrock slopes. To summarize, this scenario postulates that eolian silt and dust, entering the study area from western sources, was only able to persist on flat, bedrock-cored uplands in the west (which would have lacked sand for saltation), and in protected areas behind isolated sandstone uplands.

Scenario 2

In Scenario 2, loess was initially deposited broadly, across the landscape, but much of it was later remobilized and redistributed downwind. Saltating sand, sometimes accumulating in outwash valley trains as the ice sheet was melting, helped deflate, (re)mobilize, and remove this loess from unprotected areas. Just as in Scenario 1, eolian silt accumulated and persisted on the bedrock uplands in the western part of the study area, because these sites were well above (and upwind of) the main sand deposits of the central Chippewa Valley. The main difference on the ground occurs at “protected” sites within the transportation surface, where loess was not only preserved, but in some locations was buried by a second deposit of the “remobilized” loess.

Although both scenarios help explain the overall pattern of loess across the transportation surface, the model presented in Scenario 2 better fits the pattern seen on the ground, that is, where loess in the lee of many of the isolated bedrock ridges often exceeds 2 m in thickness, even though it is far from the (original) loess sources. Such an example occurs at the Geist farm orchard, in the immediate lee of a sandstone ridge (Fig. 8). Like other ridges on the loess transportation surface, the windward side of this ridge has only a minimal (less than ≈40 cm) cover of silty-sand regolith, while the lee side is blanketed with thick loess. Low-relief areas in lowlands near the ridge vary in loess cover, but seldom have more than ≈45 cm of loess, even as the thick (>195 cm) blanket of loess on the lee side of the ridge extends for ≈3 km downwind. Within this area of thick loess, but close to the ridge crest, I recovered a core, down to the sandstone bedrock at 585 cm. Grain-size data from the core provide insight as to the origins of loess at this site and to the two scenarios discussed earlier. In a thin zone immediately above the sandstone bedrock, the loess is sandy, as expected due to mixing of the earliest loess deposits with the underlying sandstone bedrock and its residuum (Fig. 9). Above that zone is ≈1.4 m of silt-rich loess with almost no sand. I interpret this as an earlier (i.e., the initial) loess deposit, formed by long-distance transport of silt in high suspension. Very little sand would have been transported at this time, perhaps due to weaker winds, widespread permafrost conditions, or a vegetation cover. The 1.4 m thickness would have been typical for loess in this area, taking into account the rate at which the loess cover thins across the low-relief bedrock uplands east of the Mississippi River. Upward in the core, this silt-rich zone abruptly ends in a sandy layer at 360 cm depth. All of the loess above this layer is variously sandy, with a particularly sandy zone between 120 and 80 cm depths. Some of this loess has sand contents >30% (Fig. 9). I interpret this 360-cm-thick, upper zone of sandy loess as having formed during a second depositional interval, when saltating sands were commonplace on the landscape. At this time, loess was likely being re-entrained by saltating sand and transported downwind. Periods of particularly strong winds drove enough sand over the ridge to form sandy zones in the upper part of the loess at the Geist site. Spatially, the sand contents in the upper 2 m of loess decrease rapidly downwind from the ridge (Fig. 8B).

Figure 8. Topography, soils, and loess cover near the Geist core site, on a small, isolated, sandstone ridge in the western part of the study area. Symbology for the loess cover and soils follows that of Fig. 3. Graduated circle maps of loess (A) thickness and (B) sand content. The data in B derive from an amalgamated sample of loess taken by hand auger, and thus reflect the average sand content within that depth interval.

Figure 9. Depth plots of various grain-size fractions and ratios from the Geist site.

Evidence that could point to a second period of loess deposition in the region (and hence, support Scenario 2) has been reported in other studies. In thick loess on uplands in the western part of the study area, Schaetzl et al. (Reference Schaetzl, Forman and Attig2014) reported that sand contents and modal grain-size values tend to increase nearer the surface. One of these sites (Henning 2) is located on 540 cm of loess, about 100 m southeast of the crest of a ridge. The loess at this site contained considerable amounts of sand, whereas at two other sites on the same ridge (Henning 1 and 3) but ca. 100–300 m farther downwind, the loess lacked a near-surface sandy zone. Instead, the loess here was uniformly silty. The thick loess at the Henning sites is similar to that at the Geist site—sandy at sites near the ridge crest, but with far less sand only slightly farther downwind.

Both the data from the distribution of loess (relative to isolated, sandstone uplands), as well as the increases in sand in the upper parts of the loess deposits in the lee of these uplands, point to an early, initial period of loessfall, followed by an event (driven by saltating sand) during which much of this loess was then redistributed. At this time, additional loess was deposited in protected sites in the lee of bedrock uplands (Figs. 5–8). Areas between the ridges were largely scoured clean of loess, although in some lowlands, thin (<45 cm) deposits of loess remain, probably because these areas were wet enough to retain a dense vegetation cover. Thus, data from the field tend to support Scenario 2.

Chronology

Sorting out the chronology of loess deposition in the study area could help our understanding of the paleoenvironmental conditions that might have driven the second period of loess erosion and deposition. Only a limited suite of ages exist, however, for what may have been the “first wave” of Peoria loess deposition in western Wisconsin. In their review of loess in the midcontinent, Bettis et al. (Reference Bettis, Muhs, Roberts and Wintle2003) reported that Peoria Loess began to accumulate across the Central Lowlands between ca. 23,000 and 22,000 14C yr BP. For a site near the Mississippi River valley, several tens of kilometers south of the study area, Leigh and Knox (Reference Leigh and Knox1993) reported a basal age of the Peoria Loess of 24,250 ± 970 yr BP (calibrated to ≈28,365 ± 966 cal yr BP). Within the study area, Schaetzl et al. (Reference Schaetzl, Forman and Attig2014) reported several optically stimulated luminescence (OSL) ages on loess immediately overlying bedrock ridges in the western part of the study area (Fig. 10). Their data suggest that (initial) loessfall may have begun at some locations in the study area by ca. 24–23 ka. However, the OSL data also suggest that at some sites, loess deposition began much later, ca. 16–13 ka. I suggest that the latter ages represent a second period of loess deposition/remobilization. OSL data from Schaetzl et al. (Reference Schaetzl, Forman and Attig2014) also suggest that loess continued to accumulate at protected sites for thousands of years, into the Early Holocene.

Figure 10. Optically stimulated luminescence (OSL) ages (and their depths) on loess from five sites in the study area, as reported by Schaetzl et al. (Reference Schaetzl, Forman and Attig2014).

These data and interpretations support widespread sand and loess remobilization within the study area. The most likely period for such an event would have coincided with cold climatic conditions shortly after the LGM, which in various locations in Wisconsin was between ca. 26 and 21 ka (Carson et al., Reference Carson, Hanson, Attig and Young2012; Schaetzl et al., Reference Schaetzl, Forman and Attig2014), when fresh deposits of outwash sand would have been accumulating within the Chippewa River valley. Considerable evidence also indicates that saltation here was driven by strong WNW winds (Schaetzl et al., Reference Schaetzl, Nyland, Kasmerchak, Breeze, Kamoske, Thomas, Bomber, Grove, Komoto and Miller2021), on a permafrost-rich landscape that likely had minimal vegetation cover. Sand wedges in the western part of the study area confirm that saltating sand and permafrost were coincident on this landscape between ca. 19.3 and 14.7 ka, that is, during and shortly after the LGM (Schaetzl et al., Reference Schaetzl, Nyland, Kasmerchak, Breeze, Kamoske, Thomas, Bomber, Grove, Komoto and Miller2021). Similar features occur in southeastern Minnesota and northeastern Iowa, west and southwest of the study area (Mason et al., Reference Mason, Nater, Bell and Hobbs1992; Walters, Reference Walters1994). Frequently occurring ventifacts (on quartzite cobbles) on landscapes in and surrounding the study area suggest that the interval of saltating sand was intense and prolonged (Cahow, Reference Cahow1976; Holmes and Syverson, Reference Holmes and Syverson1997; Johnson, Reference Johnson2000; Schaetzl et al., Reference Schaetzl, Nyland, Kasmerchak, Breeze, Kamoske, Thomas, Bomber, Grove, Komoto and Miller2021). Ventifacts and wind-eroded surfaces, which are indicators of paleo-permafrost (Demitroff, Reference Demitroff2016), are particularly well developed along the north and south margins of the isolated bedrock uplands. Here, abraded rocks protrude from the land surface, while just a few hundred meters away, directly downwind from the same ridge, thick loess has accumulated (Fig. 11). This pattern suggests that winds were accelerating around the margins of the uplands, as they would have on their ascent up the windward side of the upland. This effect is not unlike what happens at snow fences, where snow drifts form on the lee side of the fence, even as winds are diverted around the ends of the fence.

Figure 11. Boulders and cobbles—many of them ventifacts—protrude from a wind-eroded surface, a few hundred meters north of a sandstone ridge in the loess transportation surface. Erosion is just as pronounced in the forest, but is not visible in the photo. Thick (>3 m) loess occurs downwind (ESE) of this ridge, less than 1 km from this site. Winds must have been particularly strong around the edges of ridges like this to so effectively abrade the land surface and the rocks. Photo by the author.

Thus, it is likely that much of the sand mobilization on the study area landscape may have coincided with a postglacial interval of permafrost (with its minimal vegetation cover) or, as has been documented for similar landscapes in Europe, while the permafrost was thawing (Kasse, Reference Kasse1997; Van Huissteden et al., Reference Van Huissteden, Vandenberghe, Van der Hammen and Laan2000). Thawing/degrading permafrost here may have led to an overall drier land surface, as infiltration rates and water storage capacities in near-surface sediments increased, facilitating sand mobilization.

Loess transportation systems II: transport across low-relief landscapes

As discussed earlier, transport of eolian silt across the sandy lowlands of the study area, up, over, and around isolated bedrock uplands, could only have been accomplished by strong winds driving saltating sands across the landscape. This process would have been optimal on low-relief landscapes, where sands are abundant (Figs. 3 and 4). The isolated sandstone uplands discussed earlier are the main topographic obstructions on this otherwise low-relief surface.

Loess in the traditional sense, that is, with silt loam textures, is extremely rare on this transportation surface, as there are few topographic obstructions to shelter it from saltating sands (Fig. 3). Eolian sediment—perhaps remnant deposits of poorly sorted, saltation sand/silt—is present on flatter upland sites, but even there it is so thin and sandy that local soil surveys failed to recognize it (Fig. 7). At almost 30 sites I examined across the transportation surface (all low, upland sites with minimal slope), eolian sediment is absent. Instead, these sites typically have a mantle of sandy loam till or residuum. At six additional sites, the surface sediment was well-sorted, fine, eolian sand.

Initial, broad-based examinations of the loess cover on this transportation surface, as indicated on local soil surveys, reveal several important patterns. First, loess deposits (as mapped in the soil surveys) have distinctly linear “edges” that align along NW-SE or WNW-ESE. Many of these “edges” are in the lee of a topographic obstruction such as a bedrock upland or—interestingly—the Late Wisconsin moraine (Fig. 12). Loess covers far more of the landscape in the “shadow” of these obstructions (to their east-southeast) than elsewhere on the transportation surface. Like many of the loess deposits, sand stringers to the immediate west of the study area have the same orientation, indicating that winds strong enough to drive saltating sand were most commonly from the NW or WNW (Schaetzl et al., Reference Schaetzl, Larson, Faulkner, Running, Jol and Rittenour2018). These patterns indicate that loess can accumulate and/or be protected not only in the lee of bedrock uplands but in the lee of wide, hummocky moraines—anything that can stop saltating sand.

Figure 12. Distribution and thickness of loess, sandy bedrock, and topography across the study area and the loess transportation surface. Dashed lines indicate the noticeably “linear” edges to loess deposits. The symbol legend is similar to that in Fig. 5.

Although loess deposits are generally absent across the transportation surface, loess is widespread downwind (east) of the Black River. Loess here is typically 40–70 cm thick, and often slightly thicker near the river. In contrast, the patchy, poorly sorted eolian sediment within the transportation surface is typically 20–50 cm thick. This pattern fits well with the LTSM of Mason et al. (Reference Mason, Nater, Zanner and Bell1999)—saltating sand on the loess transportation surface has deflated silt from this landscape, but because these sands were unable to cross the wide (and in places, deep) valley of the Black River (Figs. 12 and 13), silt-rich loess could accumulate in downwind areas. The sand was largely stopped at the river, just as it was at the isolated sandstone uplands farther to the west, on the same transportation surface. This pattern does not manifest itself relative to the much smaller tributaries of the Eau Claire River, suggesting that sand was able to cross these valleys. Thus, the geometry and width of river valleys and other topographic obstructions appears to also figure into the LTSM (Putman et al., Reference Putman, Jansen and Follmer1988).

Figure 13. Images of the Black River in the study area. Photos by the author.

To further examine the hypothesis that sands were driven across the transportation surface on westerly winds from upwind outwash sources, I sampled (1) gravel pits cut into outwash deposits of the Chippewa River, (2) eolian sands on upland sites on the transportation surface, and (3) fluvial sands within the Eau Claire River valley. The data indicate that the sands within the Chippewa River valley are commonly enriched in “heavy” minerals, whereas sands are much more quartz-rich on the transportation surface (Fig. 14). This pattern supports the model of eolian transport of sands across the loess transportation surface, such that the lightest minerals became enriched en route.

Figure 14. Locations and quantities of quartz and chert in sands from gravel pits and other sandy deposits within the study area.

Finally, I performed a more detailed examination of sand and silt contents of eolian sediments across the study area, and on the transportation surface in particular, to further verify the efficacy of the LTSM (Fig. 15). The sediments on the transportation surface, which are assumedly reflective of the sediment as it crossed the landscape, are dominated by fine and very fine sand and have low (but not insignificant) contents of silt (Fig. 16). As expected, silt contents on the transportation surface are much higher at sites downwind of isolated bedrock ridges. Mean weighted particle size (MWPS) data (not shown) confirm these predictable spatial patterns; eolian samples on the transportation surface have high MWPS values, which decline abruptly across the Black River and in areas downwind of bedrock uplands. Notably, upland sites north of the transportation surface but south of the end moraine are covered with silt-rich loess. This area was protected from saltating sand being driven by NW and WNW winds, and hence, silt-rich loess was retained on the landscape.

Figure 15. Graduate circle maps of the silt contents of the sampled eolian sediment across the study area. Samples that have sand as the dominant grain-size are shown in yellow; silt-rich samples are in blue.

Figure 16. Grain-size curves for six representative samples of eolian sediment across and beyond the loess transportation surface. Graduated sizes of circles on the map depict the ratio of silt/sand within the sediment.

CONCLUSIONS

The theory behind a loess transportation surface, first introduced by Mason et al. (Reference Mason, Nater, Zanner and Bell1999), can often be used to explain the thickness, texture, and patchy distribution of various kinds of eolian sediments, particularly loess. In the immediate postglacial period, west-central Wisconsin had all the essential components necessary for loess destabilization and transportation—abundant sands from a variety of sources; an interval in the geologic past with cold, windy cold conditions and (likely) minimal vegetation cover due to permafrost; and loess that was either being brought in as dust in suspension or was already present on the landscape. South of the study area, loess transportation surfaces are less common, probably because of a denser vegetation cover that precluded the generation of large amounts of saltating sand (Mason et al., Reference Mason, Nater, Zanner and Bell1999). Today, the western Wisconsin study area has only patchy loess cover, with most of the loess (and the thickest deposits) occurring in areas that were protected from saltating sands that were being driven on strong westerly and northwesterly winds. Loess is generally absent from sites exposed to those saltating sands. Loess deposits are present, and often quite thick, at protected sites, such as those in the lee of (1) the Black River valley and (2) large, isolated bedrock uplands. Even the Late Wisconsin moraine was generally able to protect the landscape to its southeast from deflation of silt by saltating sand, resulting in a loess cover in its lee (Fig. 17). The moraine, the Black River, and the bedrock uplands were all able to stop or hinder the effects of saltating sand, while allowing silt in suspension to continue on, downwind. The presence of thick loess deposits in the lee of these uplands, combined with evidence of intense eolian erosion around their windward margins, portends that the winds were very strong at this time. Evidence also exists for an early period of dust deposition from distant, westerly sources, followed by a period (ca. 16–13 ka) when much of this loess may have then been re-entrained and deposited farther downwind, in protected sites. This later loess often is slightly sandier.

Figure 17. A generalized, summary diagram of the distribution and thickness of loess across the study area, as it pertains to topography and sources of potentially saltating sand. The A-B transect across the landscape is shown as a general topographic and sedimentologic profile in the center of the figure.

In summary, this work supports the contention of Mason et al. (Reference Mason, Nater, Zanner and Bell1999, p. 223) that loess has “a critical but indirect role in the regional spatial pattern of loess transport and deposition through its effect on the movement of saltating sand.” Across my study area, loess transportation surfaces take two forms: (1) an extensive, low-relief landscape with only scattered patches of silty-sandy eolian sediment, mainly on broad uplands; and (2) the windward slopes of bedrock uplands, which may even have acted as sand ramps.

Acknowledgments

The hundreds of samples that form the backbone of this study were collected over several years with the help of numerous colleagues, friends, and students. Some of the samples were part of Kristy Gruley's master's thesis. Pete Scull, David Schaetzl, John Attig, and Greg Hamann also assisted with field sampling. Garry Running, Phil Larson, Doug Faulkner, and their students from UW–Eau Claire did the coring at the Geist site. I am grateful to many landowners who allowed me to do extensive sampling on their land, particularly Joann and Roger Henning, Kris Brown, and Wayne Geist. Ha-Jin Kim assisted with the graphics, Andy Finley analyzed the grain-size data for modal values, and Chris Baish helped with quality-control checks on the large data sets involved in a study like this. Finally, I am grateful to Joe and Christina Hupy for their hospitality—housing me (many times) while I was in the field. Two anonymous reviewers were of great help in review and revision stages of this project.

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, 2326.10.1130/G34857.1CrossRefGoogle 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, 6188.10.1016/S0012-8252(98)00035-XCrossRefGoogle 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, 6167.10.1016/1040-6182(93)90054-JCrossRefGoogle 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, 1331813326.10.1029/2019GL083951CrossRefGoogle 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, 107085.10.1016/j.quascirev.2021.107085CrossRefGoogle 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, 19071946.10.1016/S0277-3791(03)00169-0CrossRefGoogle 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, 34153433.10.1175/1520-0442(2004)017<3415:PMSOTW>2.0.CO;22.0.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, 583589.10.1016/j.yqres.2012.08.005CrossRefGoogle 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, 173188.10.1111/j.1502-3885.2001.tb01221.xCrossRefGoogle Scholar
COHMAP Members, 1988. Climatic changes of the last 18,000 years: observations and model simulations. Science 241, 10431052.10.1126/science.241.4869.1043CrossRefGoogle 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, 1429.10.1016/j.quascirev.2019.07.003CrossRefGoogle Scholar
Demitroff, M., 2016. Pleistocene ventifacts and ice-marginal conditions, New Jersey, USA. Permafrost and Periglacial Processes 27, 123137.10.1002/ppp.1860CrossRefGoogle 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, 7595.10.1016/j.geomorph.2016.04.016CrossRefGoogle 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, 566572.10.2136/sssaj1965.03615995002900050027xCrossRefGoogle Scholar
Frazee, C.J., Fehrenbacher, J.B., Krumbein, W.C., 1970. Loess distribution from a source. Soil Science Society of America Proceedings 34, 296301.10.2136/sssaj1970.03615995003400020032xCrossRefGoogle Scholar
French, H.M., Millar, S.W.S., 2014. Permafrost at the time of the Last Glacial Maximum (LGM) in North America. Boreas 43, 667677.10.1111/bor.12036CrossRefGoogle Scholar
Gardner, R.A.M., Rendell, H.M., 1994. Loess, climate and orogenesis: implications of South Asian loesses. Zeitschrift für Geomorphologie 2, 169184.10.1127/zfg/38/1994/169CrossRefGoogle 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, 108115.10.1016/j.quaint.2014.06.039CrossRefGoogle Scholar
Hole, F.D., 1943. Correlation of the glacial border drift of north central Wisconsin. American Journal of Science 241, 498516.10.2475/ajs.241.8.498CrossRefGoogle 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, 574583.10.1016/j.yqres.2011.02.003CrossRefGoogle Scholar
Jacobs, P.M., Mason, J.A., Hanson, P.R., 2012. Loess mantle spatial variability and soil horizonation, southern Wisconsin, USA. Quaternary International 265, 4253.10.1016/j.quaint.2012.01.017CrossRefGoogle 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, 295311.10.1002/(SICI)1099-1530(199709)8:3<295::AID-PPP256>3.0.CO;2-03.0.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, 118.10.1016/S0169-555X(00)00040-4CrossRefGoogle 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, 282289.10.1006/qres.1993.1035CrossRefGoogle Scholar
Leighton, M.M., Willman, H.B., 1950. Loess formations of the Mississippi Valley. Journal of Geology 58, 599623.10.1086/625772CrossRefGoogle Scholar
Li, Y., Shi, W., Aydin, A., Beroya-Eitner, M.A., Gao, G., 2020. Loess genesis and worldwide distribution. Earth-Science Reviews 201, 102947.10.1016/j.earscirev.2019.102947CrossRefGoogle 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, 315318.10.1130/G32937.1CrossRefGoogle 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, 551571.10.1080/00045608.2015.1115388CrossRefGoogle 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, 85100.10.1016/j.aeolia.2012.11.003CrossRefGoogle 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, 7986.10.1006/qres.2001.2250CrossRefGoogle 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, 4451.10.1006/qres.1994.1005CrossRefGoogle 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, 223236.10.1016/S0169-555X(98)00112-3CrossRefGoogle 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, 38583870.10.1016/j.quascirev.2011.10.005CrossRefGoogle 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, 17191727.10.2136/sssaj2011.0303CrossRefGoogle 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, 4961.10.1006/qres.1999.2090CrossRefGoogle 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, 468481.10.1016/j.yqres.2013.06.006CrossRefGoogle 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, 235269.10.1016/j.quascirev.2018.03.024CrossRefGoogle Scholar
Nickling, W.G., 1978. Eolian sediment transport during dust storms: Slims River Valley, Yukon Territory. Canadian Journal of Earth Sciences 15, 10691084.10.1139/e78-114CrossRefGoogle 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, 91104.10.1016/j.aeolia.2017.05.005CrossRefGoogle 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, 600010.10.3389/feart.2021.600010CrossRefGoogle 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, 241247.10.1097/00010694-198810000-00004CrossRefGoogle 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, 411419.10.1016/S0033-5894(03)00040-1CrossRefGoogle Scholar
Ruhe, R.V., 1973. Background of model for loess-derived soils in the upper Mississippi Valley. Soil Science 115, 250253.10.1097/00010694-197303000-00011CrossRefGoogle Scholar
Ruhe, R.V., 1984. Loess derived soils, Mississippi valley region: I. Soil sedimentation system. Soil Science Society of America Journal 48, 859867.10.2136/sssaj1984.03615995004800040032xCrossRefGoogle 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, 11251132.10.2136/sssaj1975.03615995003900060031xCrossRefGoogle Scholar
Schaetzl, R.J., Attig, J.W., 2013. The loess cover of northeastern Wisconsin. Quaternary Research 79, 199214.10.1016/j.yqres.2012.12.004CrossRefGoogle 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, 318329.10.1016/j.yqres.2013.12.003CrossRefGoogle 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 18.10.2747/0272-3646.29.2.140CrossRefGoogle 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, 4965.10.1007/s10933-015-9862-2CrossRefGoogle 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, 769785.10.1017/qua.2017.88CrossRefGoogle 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, 277285.10.1016/j.geoderma.2012.08.001CrossRefGoogle 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, 2529.10.1080/02723646.2020.1734414CrossRefGoogle 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, 385401.10.1111/bor.12550CrossRefGoogle 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, 143155.10.1016/j.geomorph.2010.12.006CrossRefGoogle 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, 28632876.10.1002/esp.5428CrossRefGoogle Scholar
Smalley, I.J., 1966. The properties of glacial loess and the formation of loess deposits. Journal of Sedimentary Petrology 36, 669676.10.1306/74D7153C-2B21-11D7-8648000102C1865DCrossRefGoogle 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, 126.10.1016/S0012-8252(02)00066-1CrossRefGoogle 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, 32763301.10.1002/esp.5456CrossRefGoogle 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, 261273.10.1016/j.yqres.2005.02.001CrossRefGoogle 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, 14601471.10.1002/jgrf.20101CrossRefGoogle 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. 537552.10.1016/B978-0-444-53447-7.00042-8CrossRefGoogle 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, 307321.10.1016/S0341-8162(00)00085-0CrossRefGoogle 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, 269282.10.1002/ppp.3430050406CrossRefGoogle 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, 108010.10.1016/j.geomorph.2021.108010CrossRefGoogle 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, 983997.10.1016/j.geoderma.2018.11.008CrossRefGoogle 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
Figure 0

Figure 1. A reproduction of fig. 4 in the loess transportation surface paper by Mason et al. (1999).

Figure 1

Figure 2. The regional setting for this study—northern Wisconsin, USA—showing the extent of Marine Oxygen Isotope Stage 2 (MIS 2; Late Wisconsin) glaciation, the major rivers that drain to the south across the region, and some county names.

Figure 2

Figure 3. Loess deposits within the study area, as interpreted from the various county soil surveys of the Natural Resources Conservation Service (U.S. Department of Agriculture). Colors correspond to loess thicknesses. Gray areas, showing only the underlying hillshade digital elevation model (DEM), indicate areas that, according to the soil maps, lack a loess cover. As defined here, the extent of the loess transportation surface is shown, broadly, by diagonal lines. The inset box shows the extent of the landscape in this figure, on a small-scale map of the state of Wisconsin.

Figure 3

Figure 4. The extent of loess, glacial outwash, and sands within the study area and in areas farther west. Loess thickness symbology follows that in Fig. 3. Data derive from NRCS soil surveys.

Figure 4

Figure 5. Maps of loess sample locations, symbolized by thickness categories, across western Wisconsin. Inset maps show detail for selected areas.

Figure 5

Figure 6. Exposures of rock and sediment on the windward and lee sides of a sandstone upland in the study area. (A) A thin veneer of regolith mantles sandstone bedrock on the windward side of the ridge. (B) Loess > 5 m thick is exposed at the Geist core site, in the immediate lee of the bedrock ridge (see Fig. 9). Shovel for scale. (C) Row-crop agriculture flourishes in the thick loess that lies in the lee of the bedrock ridges in the distance. Photos by the author.

Figure 6

Figure 7. Topography, soils, and loess cover on and near a small, isolated, sandstone ridge (and a smaller, neighboring ridge) in the west-central study area. Soils data from NRCS soil maps.

Figure 7

Figure 8. Topography, soils, and loess cover near the Geist core site, on a small, isolated, sandstone ridge in the western part of the study area. Symbology for the loess cover and soils follows that of Fig. 3. Graduated circle maps of loess (A) thickness and (B) sand content. The data in B derive from an amalgamated sample of loess taken by hand auger, and thus reflect the average sand content within that depth interval.

Figure 8

Figure 9. Depth plots of various grain-size fractions and ratios from the Geist site.

Figure 9

Figure 10. Optically stimulated luminescence (OSL) ages (and their depths) on loess from five sites in the study area, as reported by Schaetzl et al. (2014).

Figure 10

Figure 11. Boulders and cobbles—many of them ventifacts—protrude from a wind-eroded surface, a few hundred meters north of a sandstone ridge in the loess transportation surface. Erosion is just as pronounced in the forest, but is not visible in the photo. Thick (>3 m) loess occurs downwind (ESE) of this ridge, less than 1 km from this site. Winds must have been particularly strong around the edges of ridges like this to so effectively abrade the land surface and the rocks. Photo by the author.

Figure 11

Figure 12. Distribution and thickness of loess, sandy bedrock, and topography across the study area and the loess transportation surface. Dashed lines indicate the noticeably “linear” edges to loess deposits. The symbol legend is similar to that in Fig. 5.

Figure 12

Figure 13. Images of the Black River in the study area. Photos by the author.

Figure 13

Figure 14. Locations and quantities of quartz and chert in sands from gravel pits and other sandy deposits within the study area.

Figure 14

Figure 15. Graduate circle maps of the silt contents of the sampled eolian sediment across the study area. Samples that have sand as the dominant grain-size are shown in yellow; silt-rich samples are in blue.

Figure 15

Figure 16. Grain-size curves for six representative samples of eolian sediment across and beyond the loess transportation surface. Graduated sizes of circles on the map depict the ratio of silt/sand within the sediment.

Figure 16

Figure 17. A generalized, summary diagram of the distribution and thickness of loess across the study area, as it pertains to topography and sources of potentially saltating sand. The A-B transect across the landscape is shown as a general topographic and sedimentologic profile in the center of the figure.