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Time Factor and the Genesis of Soils on Early Wisconsin Till

Published online by Cambridge University Press:  01 January 2024

D. R. Hensel*
Affiliation:
Agronomy Department, Purdue University, Lafayette, Indiana, USA
Joe L. White
Affiliation:
Agronomy Department, Purdue University, Lafayette, Indiana, USA
*
3Present address, Soils Department, Rutgers University , New Brunswick , N.J.
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Abstract

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Radiocarbon dates indicate that the maximum time of weathering for soils of the Tazewell substage may be about 6400 years longer than that available for weathering of soils of the Cary substage.

Detailed mineralogical and chemical studies were made of the 2–0.2 μ fractions of 0–6 in. and 30–36 in. samples from 24 sites along a traverse extending from the Cary substage across the Tazewell substage in east-central Indiana. The major clay mineral constituents of the 0–6 in. samples were illite and 14 Å material; illite and montmoril-lonite were the main components in the 30–36 in. samples. The correlation coefficients between illite content and percentage K2O for the 0–6 in. and 30–36 in. samples were 0.85 and 0.92, respectively.

The end and terminal moraines of the Tazewell substage were found to have a higher illite content than the ground moraines. This was attributed to superglacial movement and enrichment of foreign materials, i.e. mica schists from the Canadian shield, on end and terminal moraines.

The results of saturation of the clay fraction with potassium and magnesium on the proportion of 10Å, 12.7Å and 14Å spacings indicated that weathering had lowered the surface charge density of the micaceous minerals in the 0–6 in. samples to a greater extent than in the 30–36 in. samples. This effect, in addition to other weathering reactions, resulted in partially expanded micaceous minerals in the 0–6 in. samples which were much more resistant to collapse than were the minerals in the 30–36 in. samples.

The rate of weathering of K2O from the 2–0.2μ fraction of the 0–6 in. samples located on ground moraines was estimated to be about 0.1 percent per 1000 years. This value was used in estimating the ages of the morainie systems of the Tazewell in Indiana. The estimated ages were as follows: Mississinewa, (radiocarbon date) 13,140 years; Union City, 14,500 years; Bloomington, 15,500 years; Champaign, 18,700 years; Shelbyville, (radiocarbon date) 19,500 years.

The fertility status of the soils on the Tazewell has been influenced appreciably by the length of the weathering period, the potassium-supplying power of the soils decreasing with increasing age.

Type
Article
Copyright
Copyright © Clay Minerals Society 1958

Footnotes

1

Journal Paper no. 1347, Purdue University Agricultural Experiment Station, Lafayette, Indiana.

2

Grateful acknowledgement is made to the National Science Foundation for a grant (NSF G-2157) made through the Purdue Research Foundation (PRF 1254) which provided the x-ray diffraction equipment used in this study.

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