Using inhibitors to trade greenhouse gas emission for ammonia losses in paddy soil: A zero-sum game

Nitrogen (N) amendment of soil ecosystems alters GHG fluxes to the atmosphere by increasing nitrous oxide (N2O) emission and affecting methane (CH4) uptake in well-aerated soils. Although nitrification inhibitors (NIs) can decrease N2O emission, this may alter the rate of ammonia (NH3) volatilizatio...

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Published in:Environmental technology & innovation 2022-11, Vol.28, p.102547, Article 102547
Main Authors: Lin, Yu-Pin, Ansari, Andrianto, Ngoc-Dan Cao, Thanh, Shiau, Yo-Jin, Lur, Huu-Sheng, Muzaffar, Adnan, Wunderlich, Rainer Ferdinand, Mukhtar, Hussnain
Format: Article
Language:English
Subjects:
Cultivars
Emission
Inhibitors
Nitrogen
Soil
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Summary:Nitrogen (N) amendment of soil ecosystems alters GHG fluxes to the atmosphere by increasing nitrous oxide (N2O) emission and affecting methane (CH4) uptake in well-aerated soils. Although nitrification inhibitors (NIs) can decrease N2O emission, this may alter the rate of ammonia (NH3) volatilization, crop yield, and soil CH4 fluxes by directly or indirectly affecting methane-oxidizing bacteria, causing severe environmental and economic damages. Here, we measured the response of gaseous N loss (N2O + NH3) and GHG fluxes (CH4 + direct N2O + indirect N2O) to the intensive application of three different rates of DCD (15 to 45 kg ha−1) and DMPP (3 to 9 kg ha−1) in N fertilized soils imposed upon six different rice cultivars. N addition increased NH3 volatilization by several orders of magnitude, N2O emission by 7- to 10-fold, and CH4 emission by 2- to 4-fold. DCD and DMPP strongly inhibited the N2O emission and, to a lesser extent, CH4 emission but promoted greater NH3 losses in a dose-dependent manner. The soil receiving urea with inhibitors exhibited up to 62.7% additional NH3 volatilization than untreated (inhibitor-free) soils over the rice growth cycle. Considering the estimated indirect N2O emission from deposited NH3, the overall inhibitory effect of nitrification inhibitors (at different application rates) ranged from 17.4% to 36.6% (reduction) for global warming potential and -6.7% to -45.9% (increase) for nitrogen losses. Collectively, our results suggest moderate inhibition of global warming potential but inadequate reduction of gaseous nitrogen losses by NIs, which were outweighed by increased NH3 volatilization. Consequently, NIs appear to be a potentially double-edged sword when targeting to diminish gaseous nitrogen losses from N fertilized soils. [Display omitted] •N fertilization significantly enhanced the emission of NH3, CH4 and N2O.•Higher inhibitory effect of DCD and DMPP for N2O than CH4 fluxes.•DMPP exhibited a similar inhibitory effect to DCD at five-fold low application rates.•NIs appear to be a double-edged sword in diminishing gaseous nitrogen losses.
ISSN:2352-1864
2352-1864
DOI:10.1016/j.eti.2022.102547