Biochemical effects of banding limit the benefits of nitrification inhibition and controlled-release technology in the fertosphere of high N-input systems
Chelsea K. Janke
A E , Ryosuke Fujinuma A C , Phil Moody B and Michael J. Bell A D
+ Author Affiliations
- Author Affiliations
A School of Agriculture and Food Sciences, University of Queensland, Australia.
B Landscape Sciences, Department of Environment and Science, Queensland State Government, Australia.
C Present address: Department of Natural Sciences, International Christian University, Tokyo, Japan.
D Centre for Plant Science, Queensland Alliance for Agriculture and Food Innovation, University of Queensland, Australia.
E Corresponding author. Email: chelsea.stroppiana@uq.net.au
Soil Research 57(1) 28-40 https://doi.org/10.1071/SR18211
Submitted: 23 July 2018 Accepted: 13 November 2018 Published: 10 December 2018
Abstract
Enhanced efficiency fertilisers (EEFs) may have an important role in improving nitrogen (N) use efficiency in agricultural systems. The performance of EEFs when applied by broadcasting and incorporation is well documented; however, little information is available for sub-surface banded N-fertiliser. This study aimed to determine the effectiveness of EEFs within the fertosphere in several soils. This was determined by: (i) establishing the key chemical effects and N-transformation activity within a urea band, and (ii) contrasting these findings with nitrification inhibitor (NI)-coated urea and a controlled-release polymer-coated urea (PCU). A 112-day incubation experiment was conducted with the EEFs band-applied in three contrasting soils with a history of sugarcane production. In standard urea and NI-urea treated soils, the pH within the fertosphere significantly increased to a maximum of ~pH 9.2–9.3. Alkaline conditions and high ammonium concentrations promoted elevated aqueous ammonia concentrations, resulting in complete nitrification inhibition. The PCU granules released ~40% of total urea content within 14 days, followed by subsequent release at significantly lower rates. The initial rapid urea release was attributed to damaged polymer coats, while close proximity of neighbouring granules within the band may have contributed to the subsequent slower release phase through reduced concentration gradients and restricted diffusion from granules. Variation between soils suggests that soil properties such as clay content and pH buffer capacity may influence urea hydrolysis, but not nitrification. These results suggest that both NI and controlled-release technology may not have the expected impacts on N transformations and availability when applied in a concentrated band.
Additional keywords: fertiliser, nitrogen, nitrification inhibitors, polymers, soil fertility.
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