Modelled Quantification of Different Sources of Nitrogen Inefficiency in Semi-Arid Cropping Systems

Most dryland grain growers in Australia retain all or most of their crop residues to protect the soil from erosion and to improve water conservation but retaining stubbles with a high carbon-to-nitrogen (C:N) ratio can affect N availability to crops. A simulation experiment was conducted to investigate the effects of N fertilizer application rate and residue retention on soil N dynamics. The simulation used seven N fertilizer application rates (0, 25, 50, 75, 100, 150 and 200 kg N ha(-1)) to wheat (Triticum aestivum) over 27 years (1990-2016) at four locations across a gradient in annual rainfall in Victoria, Australia. Nitrogen immobilization, denitrification and N leaching loss were predicted and collectively defined as sources of N inefficiency. When residues were retained, immobilization was predicted to be the biggest source of inefficiency at all simulated sites at N application rates currently used by growers. Leaching became a bigger source of inefficiency at one site with low soil water-holding capacity, but only at N rates much higher than would currently be commercially applied, resulting in high levels of nitrate (NO3-) accumulating in the soil. Denitrification was an appreciable source of inefficiency at higher rainfall sites. Further research is necessary to evaluate strategies to minimize immobilization of N in semi-arid cropping systems.

Automated summary

The study found that retaining crop residues with a high carbon-to-nitrogen ratio can affect nitrogen availability to crops, with nitrogen immobilization becoming the primary source of inefficiency when residues are retained at current nitrogen application rates. Further research is needed to evaluate strategies to minimize nitrogen immobilization in semi-arid cropping systems.