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Land Restoration Investigation Unit, Dep. of Agriculture, Newcastle Univ., Newcastle upon Tyne, NE1 7RU, UK.
ADAS, Anstey Hall, Trumpington, Cambridge CB2 2LF, UK.
* Corresponding author (robin.davies{at}newcastle.ac.uk).
ABSTRACT
Anaerobic conditions develop below about 1-m depth in soil stockpiles and this can lead to an accumulation of ammonium (NH+4) and transformations of a normally relatively inert organic-N pool within the soil. After reinstatement of the soil from the stockpile, the NH+4 may rapidly be transformed to nitrate (NO–3) and lost from the soil with the labile organic-N. These losses may lead to a pollution risk in addition to the loss of a resource. The magnitude of N losses were measured from a soil that had been reinstated for agricultural use after being stored in a stockpile for 12 yr. Nitrogen movement in the soil profile and losses into the water-course were monitored for 2 yr beginning immediately after reinstatement. Relatively large movements of N were detected within the soil profile and large losses to the atmosphere and/or water-courses were estimated. Over the 2-yr monitoring period, 2449 kg ha–1 of N was lost from the soil profile; 90% of this was not accounted for either in the soil or in the runoff or drainage water as mineral-N and was presumed to have entered either the atmosphere or aquatic environment as organic-N. To aid remedial measures, the proportion entering the atmosphere as nitrogen and nitrous oxides or the aquatic environment as organic-N, needs further investigation.
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