Mineralisation of 15N-labelled sheep manure in soils of different texture and water contents

Abstract

In order to investigate the effect of soil water and texture on C and N mineralisation of applied organic matter, sheep manure was sandwiched between two halves of intact soil cores and incubated at 20°C. The soils contained 10.8% (L1), 22.4% (L3) and 33.7% (L5) clay, respectively, and were drained to seven different matric potentials in the range –15 to –1,500 hPa. Evolution of CO2-C was determined during 4 weeks of incubation. Contents of NO3 –-N, 15N and microbial biomass N were determined at the end of the incubation. The net release of CO2-C from the manure (estimated as the difference between soils with and without manure) and the total CO2-C evolution from soils with manure was not related to soil water content. Most CO2-C evolved from manure-amended soils in the least clayey L1 soil. The manure caused immobilisation of soil NO3 –-N but the soil matric potential had no major effects on the net NO3 –-N production. Less than 1% of the manure 15N was found as NO3 –-N at the end of the incubation. When unamended, the sandy L1 soil held the least N in microbial biomass but the largest increases in biomass N caused by manure application were found in this soil. Despite the higher increases in microbial biomass N in the L1 soil, the total content of microbial biomass N in soils with manure application peaked in the most clayey soil (L5). The recovery of manure 15N at the end of the incubation ranged from 89% to 102%. The variation in 15N recovery was not related to soil clay content nor to soil matric potential. The experimental set-up was designed to mimic field conditions where manure is left as a discrete layer surrounded by structurally intact soil. In this situation the soil clay content and the soil water level appeared to have little influence on the C and N turnover in the manure layer.