Table 5. Soil units and landslides.
| Soil unit | Parent material | Number of landslides | Percentage of landslides |
|---|---|---|---|
| Gosport | bedrock | 79 | 54.5% |
| Armster | till | 25 | 17.2% |
| Knox-Gosport | bedrock & loess | 15 | 10.3% |
| Knox | loess | 7 | 4.8% |
| Shelby | till | 6 | 4.1% |
| Kennebec | alluvium | 5 | 3.5% |
| Haynie | alluvium | 4 | 2.8% |
| Martin | bedrock | 1 | 0.7% |
| Sharpsburg | loess | 1 | 0.7% |
| Vinland | bedrock | 1 | 0.7% |
| Aquents | alluvium | 0 | 0% |
| Chase | terrace | 0 | 0% |
| Grundy | loess | 0 | 0% |
| Judson | alluvium | 0 | 0% |
| Onawa | alluvium | 0 | 0% |
| Pawnee | till | 0 | 0% |
| Reading | terrace | 0 | 0% |
| Wabash | alluvium | 0 | 0% |
| unknown | 1 | 0.7% | |
| Totals | 145 |
The data presented in table 5 show that soils developed on bedrock are the most susceptible to landslides. This agrees with the geologic data that showed a high percentage of landslides in bedrock (table 2). The next highest percentage of landslides is in soils developed on glacial drift, followed by soils developed on loess and alluvium. The NRCS soil maps include the Atchison formation with soils developed on the glacial drift. Thus, the landslides in the Atchison formation are included with the landslides in glacial drift in table 5.
Fig. 13. The frequency of recent landslides for a given slope angle. The frequencies were determined by counting the number of landslides for 5-degree intervals of slope angle. The average slope angle for recent landslides is 22.2 degrees.
Landslides on slopes with low slope angles highlight the role clay layers within the shale formations play in slope stability. Above the Clay Creek Limestone Member of the Kanwaka Shale is a 20-cm (8-in) clay layer, with a high percentage of clay-sized particles and expansive clay minerals. In the Jackson Park area, several recent landslides were mapped above the Clay Creek Limestone, placing the failure planes of the landslides in the 20-cm clay layer (fig. 14). As fig. 14 shows, the portion of the failure surface that runs through the clay layer has a very low dip. This and other thin clay layers may be controlling some of the recent landslides, including those on gentle slopes (5 degrees to 15 degrees).
Fig. 14. Diagram of the failure plane of a landslide in the Kanwaka Shale. The clay layer above the Clay Creek Limestone Member is weak, and the failure plane of the landslide would be located within this layer. Earth slides and earth flows on gentle slopes (5 degrees to 15 degrees) may be the result of thin, weak clay layers.
Figure 13 shows a decrease in frequency of recent landslides on slopes greater than 22 degrees. This decrease may result from the fact that steep slopes tend to have thinner soils and that the percentage of the area with steep slopes is relatively small. The steepest slopes are in limited areas along the bluffs of the Missouri River and its tributaries. Normalization of the data to the percentage of the area with the various ranges of slope angle may provide a more realistic assessment of the role of slope angle in landsliding, but the slope data required for doing the normalization were not available when this report was written.
Fig. 15. Rose diagram showing the slope lines for the recent landslides. Two maxima are observed in the data. The first is from northeast to southeast and is related to the bluffs of the Missouri River (yellow area in figure). The second is to the northwest and may be related to ground-water flow.
Kansas Geological Survey
Web version December 22, 2000
http://www.kgs.ku.edu/Current/2000/ohlmacher/ohlmacher7.html
email:lbrosius@kgs.ku.edu