What question did this study set out to answer?

This study aims to evaluate ammonia emissions and their correlation with different urea fertilizers and inhibitors in winter wheat.

March 29, 2026Open Access

Ammonia emissions from inhibited urea fertilizers – Results on mitigation potential and wheat yield from a multisite experiment across six different regions in Germany

Key Points

This study aims to evaluate ammonia emissions and their correlation with different urea fertilizers and inhibitors in winter wheat.
Conducted coordinated field trials across 22 site-year combinations in Germany
Tested various fertilizers: urea, urea with urease inhibitors, and double-inhibited urea
Used ALPHA samplers, inverse dispersion modeling, and semi-quantitative passive flux samplers to measure ammonia emissions
Developed a linear mixed-effects model to analyze the data considering plot placement
Average ammonia emission factors were 8.0%, 3.1%, and 3.8% for urea, urea with inhibitors, and double-inhibited urea, respectively.
U+UI reduced emissions by 61% while U+UI+NI reduced emissions by 52%.
Yield was significantly impacted by inhibitor treatment, with the highest grain nitrogen yield at 164 kg N ha −1 for U+UI.

Abstract

The use of urease- and nitrification inhibitors (UI, NI) is widely accepted in agriculture. However, robust ammonia (NH 3 ) reduction factors for specific compounds and regions are missing. This study of coordinated field trials evaluated NH 3 emissions in Germany across 22 site-year combinations after the application of inhibited urea in winter wheat. Tested fertilizers were urea (U), urea with UI (U+UI), and double-inhibited urea (U+UI+NI). Ammonia emissions were determined using ALPHA samplers, inverse dispersion modeling, and semi-quantitative passive flux samplers. Improving the existing calibrated passive sampling approach, a linear mixed-effects model was developed, accounting for the placement of individual plots within the trial layout. Regardless of the fertilizer treatment, the weather covariates and the clay content significantly influenced the emission factors (EFs, expressed as NH 3 -N per unit N applied). Average EFs for the treatments were 8.0, 3.1, and 3.8% for U, U+UI, and U+UI+UI, respectively. Compared to U, the emission reduction was affected by inhibitor treatment, soil clay content, and temperature, and was highest under high N-loss scenarios. Average reductions were 61% for U+UI and 52% for U+UI+NI. The results suggest a regionalization of EFs and reduction factors. Grain N yield was significantly influenced by inhibitor treatment and was highest for U+UI with 164 kg N ha −1 . U+UI+NI featured the highest absolute yield. With a reduced grain protein concentration, this resulted in a similar grain N yield when compared to U. Combining results of emission and yield measurements, recommendations for specific production targets in winter wheat production are derived. • U+UI (2-NPT) and U+UI+NI (2-NPT + MPA) decrease NH 3 emissions by 61 and 52%. • Environmental covariates influenced emissions and the reduction by inhibitors. • Inhibitors had distinct effects on yield components, however, not always significant. • Improved Transfer Coefficient for calibrated passive sampling. • Coherent field study for new inhibitors and combined yield and emission assessment.

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