Official Series Description


Lab Data Summary

Aggregate lab data for the CHAPETT soil series. This aggregation is based on all pedons with a current taxon name of CHAPETT, and applied along 1-cm thick depth slices. Solid lines are the slice-wise median, bounded on either side by the interval defined by the slice-wise 5th and 95th percentiles. The median is the value that splits the data in half. Five percent of the data are less than the 5th percentile, and five percent of the data are greater than the 95th percentile. Values along the right hand side y-axis describe the proportion of pedon data that contribute to aggregate values at this depth. For example, a value of "90%" at 25cm means that 90% of the pedons correlated to CHAPETT were used in the calculation. Source: KSSL snapshot . Methods used to assemble the KSSL snapshot used by SoilWeb / SDE

There are insufficient data to create the lab data summary figure.


Water Balance

Monthly water balance estimated using a leaky-bucket style model for the CHAPETT soil series. Monthly precipitation (PPT) and potential evapotranspiration (PET) have been estimated from the 50th percentile of gridded values (PRISM 1981-2010) overlapping with the extent of SSURGO map units containing each series as a major component. Monthly PET values were estimated using the method of Thornthwaite (1948). These (and other) climatic parameters are calculated with each SSURGO refresh and provided by the fetchOSD function of the soilDB package. Representative water storage values (“AWC” in the figures) were derived from SSURGO by taking the 50th percentile of profile-total water storage (sum[awc_r * horizon thickness]) for each soil series. Note that this representation of “water storage” is based on the average ability of most plants to extract soil water between 15 bar (“permanent wilting point”) and 1/3 bar (“field capacity”) matric potential. Soil moisture state can be roughly interpreted as “dry” when storage is depleted, “moist” when storage is between 0mm and AWC, and “wet” when there is a surplus. Clearly there are a lot of assumptions baked into this kind of monthly water balance. This is still a work in progress.

Click the image to view it full size.



Click the image to view it full size.

Sibling Summary

Siblings are those soil series that occur together in map units, in this case with the CHAPETT series. Sketches are arranged according to their subgroup-level taxonomic structure. Source: SSURGO snapshot , parsed OSD records and snapshot of SC database .

Click the image to view it full size.

Select annual climate data summaries for the CHAPETT series and siblings. Series are sorted according to hierarchical clustering of median values. Source: SSURGO map unit geometry and 1981-2010, 800m PRISM data .

Click the image to view it full size.

Geomorphic description summaries for the CHAPETT series and siblings. Series are sorted according to hierarchical clustering of proportions and relative hydrologic position within an idealized landform (e.g. top to bottom). Most soil series (SSURGO components) are associated with a hillslope position and one or more landform-specific positions: hills, mountain slopes, terraces, and/or flats. Proportions can be interpreted as an aggregate representation of geomorphic membership. The values printed to the left (number of component records) and right (Shannon entropy) of stacked bars can be used to judge the reliability of trends. Small Shannon entropy values suggest relatively consistent geomorphic association, while larger values suggest lack thereof. Source: SSURGO component records .

Click the image to view it full size.

Click the image to view it full size.

There are insufficient data to create the 3D mountains figure.

Click the image to view it full size.

Click the image to view it full size.

Competing Series

Soil series competing with CHAPETT share the same family level classification in Soil Taxonomy. Source: parsed OSD records and snapshot of the SC database .

Click the image to view it full size.

Select annual climate data summaries for the CHAPETT series and competing. Series are sorted according to hierarchical clustering of median values. Source: SSURGO map unit geometry and 1981-2010, 800m PRISM data .

Click the image to view it full size.

Geomorphic description summaries for the CHAPETT series and competing. Series are sorted according to hierarchical clustering of proportions and relative hydrologic position within an idealized landform (e.g. top to bottom). Proportions can be interpreted as an aggregate representation of geomorphic membership. Most soil series (SSURGO components) are associated with a hillslope position and one or more landform-specific positions: hills, mountain slopes, terraces, and/or flats. The values printed to the left (number of component records) and right (Shannon entropy) of stacked bars can be used to judge the reliability of trends. Shannon entropy values close to 0 represent soil series with relatively consistent geomorphic association, while values close to 1 suggest lack thereof. Source: SSURGO component records .

Click the image to view it full size.

Click the image to view it full size.

There are insufficient data to create the 3D mountains figure.

There are insufficient data to create the 3D terrace figure.

There are insufficient data to create the 3D flats position figure.

Soil series sharing subgroup-level classification with CHAPETT, arranged according to family differentiae. Hovering over a series name will print full classification and a small sketch from the OSD. Source: snapshot of SC database .

Block Diagrams

Click a link below to display the diagram. Note that these diagrams may be from multiple survey areas.

  1. MN-2010-09-08-20 | Otter Tail County - 2001

    Typical pattern of soils and parent material in the Chapett-Sisseton-Friberg association (Soil Survey of Otter Tail County, Minnesota; 2001).

  2. MN-2010-09-08-30 | Polk County - 2003

    Typical pattern of soils and underlying material in the Chapett-Knute-Brandsvold association (Soil Survey of Polk County, Minnesota; 2003).

  3. MN-2010-09-08-32 | Polk County - 2003

    Typical pattern of soils and underlying material in the Halverson-Maddock-Chapett association (Soil Survey of Polk County, Minnesota; 2003).

Map Units

Map units containing CHAPETT as a major component. Limited to 250 records.

Map Unit Name Symbol Map Unit Area (ac) Map Unit Key National Map Unit Symbol Soil Survey Area Publication Date Map Scale
Chapett fine sandy loam, 2 to 8 percent slopes20B1193397503fbmpmn00519941:20000
Chapett fine sandy loam, 8 to 15 percent slopes, eroded20C2783397504fbmqmn00519941:20000
Chapett fine sandy loam, 15 to 30 percent slopes20E224397505fbmrmn00519941:20000
Chapett fine sandy loam, 2 to 6 percent slopes20B1650430456gfxpmn02919931:20000
Chapett fine sandy loam, 6 to 12 percent slopes, eroded20C2292430458gfxrmn02919931:20000
Chapett-Sisseton complex, 6 to 12 percent slopes, eroded760C233525435933gmmcmn11119961:20000
Chapett loam, 2 to 6 percent slopes1232B13839435573gm7rmn11119961:20000
Chapett-Sisseton complex, 12 to 20 percent slopes, eroded760D213375435934gmmdmn11119961:20000
Chapett-Dorset complex, 6 to 12 percent slopes, eroded1102C5152435525gm66mn11119961:20000
Chapett-Corliss complex, 12 to 20 percent slopes, eroded1112D3051435535gm6jmn11119961:20000
Chapett loam, 20 to 30 percent slopes1232E2730435574gm7smn11119961:20000
Chapett-Dorset complex, 1 to 6 percent slopes1102B2354435524gm65mn11119961:20000
Chapett-Corliss complex, 20 to 30 percent slopes1112E1300435536gm6kmn11119961:20000
Chapett fine sandy loam, 2 to 6 percent slopes20B50759352215cthsmn11919961:20000
Chapett fine sandy loam, 6 to 12 percent slopes, eroded20C212356352217cthvmn11919961:20000
Chapett fine sandy loam, 12 to 20 percent slopes, eroded20D25469352219cthxmn11919961:20000
Chapett fine sandy loam, 20 to 40 percent slopes20E447352220cthymn11919961:20000

Map of Series Extent

Approximate geographic distribution of the CHAPETT soil series. To learn more about how this distribution was mapped, or to compare this soil series extent to others, use the Series Extent Explorer (SEE) application. Source: generalization of SSURGO geometry .