Gradual and anthropogenic soil change for fertility and carbon on marginal sandy soils

As soils come under increasing pressure to maintain a range of ecosystem services, there is interest in how soils change over time in response to factors such as change in land-use. Many studies examining long- and short-term soil change have focused on soils with relatively high mineral and fertili...

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Bibliographic Details
Published in:Geoderma 2013-10, Vol.207-208, p.35-48
Main Authors: Tye, A.M., Robinson, D.A., Lark, R.M.
Format: Article
Language:English
Subjects:
arable soils
bedrock
carbon
Carbon loss
cations
deforestation
ecosystem services
fertilizers
Land-use change
leaching
minerals
nutrients
regolith
sandstone
sandy soils
saprolite
Sherwood sandstone
soil depth
Soil fertility
soil properties
weathering
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Summary:As soils come under increasing pressure to maintain a range of ecosystem services, there is interest in how soils change over time in response to factors such as change in land-use. Many studies examining long- and short-term soil change have focused on soils with relatively high mineral and fertility status. Therefore, the aims of this study are to explore regional change on a marginal sandy soil formed over the Sherwood Sandstone outcrop in Nottinghamshire, U.K. (750km2) and to assess changes in soil fertility as a function of the natural weathering process and land use change. The study uses data from three sources to examine differences between soil fertility properties under two major land-uses through the depth of the soil/mobile regolith (~1.6m) and into the saprolite. It is proposed that the differences reflect in part the result of historical change in land-use. From old maps we identify the land-use changes back to 1781. This allowed us to compare soils that have been under woodland cover at least since 1781 with those that were converted to arable use in major deforestation between 1781 and 1881. Soils now under woodland have low concentrations of base cations, an acid pH and a mean organic carbon concentration (0–15cm) of 2.7%. In contrast soils now under arable use have large concentrations of base cations, pH close to neutral and mean organic carbon concentration (0–15cm) of 1.7%. There is evidence in the arable soils of leaching to depth of materials from applied fertilisers and lime. These results show the rapid change in properties of soil formed in bedrock, with small concentrations of nutrients and weatherable minerals, which can result from land-use change. •An examination of soil development on marginal sandy soils•Changes with time described in the context of weathering and land use change•Conversion of land from forest/heath to largely arable use recorded from 1787•Weathering process under ancient woodland leaves a low pH soil with ~4% OC (0–30cm).•Arable soils have higher pH, lower %OC (~2%) and higher nutrient leakage.
ISSN:0016-7061
1872-6259
DOI:10.1016/j.geoderma.2013.05.004