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Keywords = nitrification inhibitors

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19 pages, 1588 KB  
Article
Effects of Nitrogen Rate and Fertilizer Type on Gaseous Nitrogen Losses and Soil Nitrogen Storage in Alkaline Maize Fields of the Hetao Irrigation District
by Yu Gao, Yunfei Di, Haibo Yang, Yuzhe Tang, Weijian Zhang, Yuncai Hu and Fei Li
Atmosphere 2026, 17(5), 504; https://doi.org/10.3390/atmos17050504 - 15 May 2026
Viewed by 233
Abstract
Gaseous nitrogen losses and residual soil nitrogen accumulation are primary drivers of low nitrogen use efficiency in alkaline irrigated cropping systems. A two-year field experiment (2019–2020) in the Hetao Irrigation District under alkaline flood-irrigated maize evaluated the effects of nitrogen rate, fertilizer formulation, [...] Read more.
Gaseous nitrogen losses and residual soil nitrogen accumulation are primary drivers of low nitrogen use efficiency in alkaline irrigated cropping systems. A two-year field experiment (2019–2020) in the Hetao Irrigation District under alkaline flood-irrigated maize evaluated the effects of nitrogen rate, fertilizer formulation, and enhanced-efficiency fertilizers—urea with urease inhibitor NBPT and ammonium sulfate with nitrification inhibitor DMPP—on NH3 volatilization, N2O emissions, post-harvest soil mineral nitrogen, and grain yield. A soil pH manipulation sub-experiment (±0.5 units, ambient pH ~8.8) was conducted to quantify the direct effect of alkalinity on volatilization. NH3 volatilization was insensitive to fertilizer formulation and inhibitor inclusion but strongly responsive to soil pH; a 0.5-unit increase in soil pH elevated volatilization efficiency by up to 25% relative to ambient conditions. N2O emissions were around 18% higher under ammonium sulfate than under urea and were reduced by 21–32% with inhibitor treatments, without increasing NH3 volatilization. Inhibitor-assisted optimized management (urea + NBPT and ammonium sulfate + DMPP) achieved higher yields and lower emission intensity than urea alone. These results confirm that NH3 and N2O losses are governed by distinct controls, and that concurrent mitigation of both pathways requires interventions that independently target each loss driver, beyond rate optimization and inhibitor application alone. Full article
(This article belongs to the Section Biosphere/Hydrosphere/Land–Atmosphere Interactions)
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21 pages, 3952 KB  
Article
Interactive Effects of Copper and Organic Matter on Dicyandiamide Efficacy in Suppressing Soil Nitrification and N2O and CO2 Emissions
by Yuhong Wen, Mulyadi, Tracy Opande, Mingkai Jiang, Zhensheng Deng, Qilin Zhu, Yanzheng Wu, Lei Meng, Ahmed S. Elrys and Nezar Samarah
Sustainability 2026, 18(9), 4513; https://doi.org/10.3390/su18094513 - 3 May 2026
Viewed by 1345
Abstract
Nitrification is a key process governing nitrogen (N) loss and greenhouse gas emissions in agricultural soils, and its regulation is strongly influenced by both chemical inhibitors and soil properties. Copper (Cu), a metal cofactor that is crucial for the function of ammonia monooxygenase [...] Read more.
Nitrification is a key process governing nitrogen (N) loss and greenhouse gas emissions in agricultural soils, and its regulation is strongly influenced by both chemical inhibitors and soil properties. Copper (Cu), a metal cofactor that is crucial for the function of ammonia monooxygenase (AMO), plays an important role in ammonia oxidation, whereas dicyandiamide (DCD) suppresses nitrification and may interact with Cu to inhibit AMO activity. However, the extent to which Cu availability and soil organic matter (SOM) jointly regulate DCD efficiency remains poorly understood. In this study, an incubation experiment was conducted using tropical paddy soils with contrasting SOM contents to explore how varying Cu levels (10 and 200 mg Cu kg−1 soil) impact DCD efficiency in regulating the nitrification process and controlling nitrous oxide (N2O) and carbon dioxide (CO2) emissions. Our results showed that DCD generally suppressed nitrification, as indicated by reduced NO3 accumulation and lower NO3/NH4+ ratios. However, the response to Cu was strongly SOM-dependent. Under low SOM, Cu addition was associated with a partial restoration of nitrification activity, suggesting a potential reduction in DCD efficiency, whereas under high SOM, this effect appeared to be attenuated, likely due to Cu complexation and reduced bioavailability. Increasing Cu levels further weakened DCD inhibition, particularly in low SOM soils. DCD significantly reduced N2O emissions, but this mitigation effect declined with Cu addition, suggesting a Cu-mediated influence on nitrification–denitrification pathways. On the other hand, CO2 emissions were reduced under DCD application and appeared to be further reduced under Cu treatments. Changes in enzyme activities and nitrifier gene abundances supported these patterns, suggesting distinct responses of AOA and AOB communities under varying SOM and Cu conditions. This study provided evidence that the interaction of Cu availability and SOM may play an important role in governing the efficacy of nitrification inhibitors. This highlights the importance of considering soil-specific chemical environments when optimizing N management strategies to reduce environmental N losses. Full article
(This article belongs to the Section Sustainable Agriculture)
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30 pages, 2594 KB  
Article
Environmental Performance and Economic Trade-Offs of Nitrification Inhibitors in Agricultural Systems: A Systematic Data Synthesis
by Colten Brickler, Yudi Wu, Simeng Li, Aavudai Anandhi and Gang Chen
Appl. Sci. 2026, 16(9), 4177; https://doi.org/10.3390/app16094177 - 24 Apr 2026
Viewed by 403
Abstract
Growing concerns over food security and greenhouse gas emissions present a dual challenge, as mitigation strategies for one often intensify the other. Nitrification inhibitors (NIs) have emerged as a promising approach to simultaneously reduce nitrous oxide (N2O) emissions and enhance crop [...] Read more.
Growing concerns over food security and greenhouse gas emissions present a dual challenge, as mitigation strategies for one often intensify the other. Nitrification inhibitors (NIs) have emerged as a promising approach to simultaneously reduce nitrous oxide (N2O) emissions and enhance crop productivity. However, their effectiveness is highly dependent on environmental conditions. To systematically evaluate the environmental controls and the economic trade-offs associated with NI application, this study presents a systematic data synthesis of 196 peer-reviewed articles, assessing the performance of three widely used NIs: dicyandiamide (DCD), 3,4-dimethylpyrazole phosphate (DMPP), and nitrapyrin. The analysis quantifies the influence of key environmental factors (e.g., temperature, soil pH, soil moisture, and soil organic carbon) on NI biodegradability, nitrogen dynamics, and N2O emissions. The results indicate that soil organic carbon has a limited effect on NI performance, whereas temperature emerges as the dominant controlling factor. Among the NIs evaluated, DCD and DMPP demonstrate the highest mitigation efficiencies, achieving N2O emission rates as low as 10−6 and 10−5 kg ha−1 d−1, respectively. An integrated economic analysis further evaluates the cost-effectiveness of NI application across major cropping systems, including corn, rice, and wheat. The findings show that DMPP and nitrapyrin applications yield the highest net economic returns in corn and rice systems (up to 860 USD and 880 USD, respectively), while wheat systems without NI application remain less profitable (approximately 330 USD). Ultimately, this study demonstrates that the practical viability of NIs depends heavily on balancing input costs with crop-specific yield gains, rather than environmental benefits alone. While NIs offer substantial greenhouse gas mitigation potential, their widespread adoption requires careful, site-specific economic evaluation to ensure that yield improvements sufficiently offset the added application costs to achieve truly sustainable agricultural practices. Full article
(This article belongs to the Special Issue Greenhouse Gas Emissions and Air Quality Assessment)
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19 pages, 1584 KB  
Article
Effect of Nitrification Inhibitors on the Soil Microbiome During Strawberry Cultivation
by Jana Maková, Renata Artimová, Soňa Javoreková, Samuel Adamec, Oleg Paulen, Alena Andrejiová, Ladislav Ducsay and Juraj Medo
Nitrogen 2026, 7(2), 39; https://doi.org/10.3390/nitrogen7020039 - 30 Mar 2026
Viewed by 881
Abstract
The application of nitrification inhibitors (Nis) with nitrogen fertilizers is increasingly used as a management strategy to improve nitrogen use efficiency in crop production systems. To evaluate the effects of Ni dicyandiamide (DCD) and 1,2,4-triazole (TZ) on the rhizosphere microbiome and strawberry yield [...] Read more.
The application of nitrification inhibitors (Nis) with nitrogen fertilizers is increasingly used as a management strategy to improve nitrogen use efficiency in crop production systems. To evaluate the effects of Ni dicyandiamide (DCD) and 1,2,4-triazole (TZ) on the rhizosphere microbiome and strawberry yield (Fragaria × ananassa Duch.), a two-year field experiment was conducted with three treatments: unfertilized control (C), mineral nitrogen fertilizer (N) applied in two doses (40 + 40 kg N ha−1 year−1), and a single nitrogen application (80 kg N ha−1 year−1) combined with nitrification inhibitors (N + Ni). Soil microbiota were assessed using cultivation-based methods and metabarcoding of 16S rRNA and ITS2 regions. Total bacterial counts on complex media increased from 5.85 to 6.15 log CFU g−1 in the N treatment, while remaining 5.89 in N + Ni. Microscopic fungi increased in fertilized treatments during spring but decreased in July of the second year. Microbial community composition differed among treatments, although sampling time explained a larger proportion of variability than fertilization. Relative abundance of Gemmatimonas decreased under N + Ni, whereas Nitrososphaera increased. Fungal Shannon diversity decreased in N + Ni, while prokaryotic diversity did not differ significantly. Despite similar levels of mineral nitrogen measured before harvest, strawberry yield increased significantly in the N + Ni treatment in the second year, reaching 109% higher values than the control and 80% higher than the N treatment. This may indicate that the fertilization regime including nitrification inhibitors influenced nitrogen availability earlier in the growing season. Full article
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14 pages, 2087 KB  
Article
On-Farm Nitrification Inhibitor Application to Urine Patches in Reducing Nitrous Oxide Emissions
by Surinder Saggar, Thilak Palmada, Peter Berben and Liyin Liang
Agronomy 2026, 16(7), 701; https://doi.org/10.3390/agronomy16070701 - 26 Mar 2026
Viewed by 570
Abstract
In livestock-grazed pastures, urine patches are a major contributor of nitrous oxide (N2O) emissions, and the use of nitrification inhibitors (NIs) has the potential to reduce N losses from urine patches using New Zealand (NZ)-devised Spikey®—a ground-based machine that [...] Read more.
In livestock-grazed pastures, urine patches are a major contributor of nitrous oxide (N2O) emissions, and the use of nitrification inhibitors (NIs) has the potential to reduce N losses from urine patches using New Zealand (NZ)-devised Spikey®—a ground-based machine that measures the change in soil conductivity from the deposited urine patches. Our ongoing research suggests that the efficacy of on-farm targeted NIs treatment requires suitable inhibitor concentrations within urine patches to be achieved to reduce N2O emissions. This study evaluates the effect of varying NI rates and volumes on reducing N2O emissions. The application rates for NIs were 1.6 g and 3.2 g dicyanamide (DCD) patch-1 and 0.96 g and 1.92 g of 3, 4-dimethylpyrazole phosphate (DMPP) patch−1, using 100, 150, and 200 mL inhibitor solutions. These rates were higher than those used in previous studies to ensure an adequate supply of inhibitors above the threshold concentration within the urine patch and to enhance the inhibitor efficacy in reducing N2O emissions. This study points to two important aspects: Determine the optimum inhibitor concentration required to eliminate, minimise/reduce N2O emissions and ensure that at the optimised amounts of inhibitor application rates, inhibitor residues are below their maximum residue level (MRL) in the food chain and environment, and eliminate their potential harm to human health. Full article
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12 pages, 2310 KB  
Article
Does Drought Regulate DMPP Effectiveness in Alleviating Maize Manganese and Phosphorus Deficiencies in High-pH Soils?
by Mathew Edung Etabo, Pablo Lacerda Ribeiro, Britta Pitann and Karl Hermann Mühling
Nitrogen 2026, 7(2), 34; https://doi.org/10.3390/nitrogen7020034 - 24 Mar 2026
Viewed by 630
Abstract
Drought will likely become more frequent and intense in Europe due to climate change, which may worsen Mn2+ and P deficiencies found in high pH soils. In this context, research investigating the effectiveness of ammonium-based nitrogen fertilizers treated with nitrification inhibitors (NIs) [...] Read more.
Drought will likely become more frequent and intense in Europe due to climate change, which may worsen Mn2+ and P deficiencies found in high pH soils. In this context, research investigating the effectiveness of ammonium-based nitrogen fertilizers treated with nitrification inhibitors (NIs) in alleviating Mn2+ and P deficiencies in such soils has been done. However, studies considering the impact of drought periods and soil texture on this topic are lacking. Therefore, we carried out a study addressing this research gap. Maize plants were grown in a greenhouse experiment, and the experimental setup comprised three factors consisting of soil texture (sand and silt loam), soil moisture (sufficient and drought), and DMPP application (with and without DMPP). The measured variables were bulk and rhizosphere soil pH, Mn2+ availability, maize biomass yield, and shoot concentration of selected macro- and micronutrients. DMPP increased shoot biomass production by 60% in silt loam under drought but not in sand soil texture. In addition, DMPP increased Mn2+ and P shoot concentrations by 38% and 21%, respectively, in the silt loam soil texture under drought. In contrast, DMPP did not alleviate the negative impact of drought on plant biomass production, Mn2+ and P shoot concentration in the sand soil texture. In conclusion, DMPP application is effective in alleviating Mn2+ and P deprivation in high pH soil subjected to drought. However, this effect was soil texture-dependent and observed in the silt loam rather than in the sand soil texture. Full article
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18 pages, 1406 KB  
Article
Iron Pools, Microbial Communities, and Greenhouse Gas Production in Subaqueous Ecosystems: Implications for Biogeochemical Cycling
by Roberta Pastorelli, Alessandra Lagomarsino, Chiara Ferronato, Arturo Fabiani, Sara Del Duca, Stefano Mocali, Livia Vittori Antisari and Gilmo Vianello
Soil Syst. 2026, 10(3), 43; https://doi.org/10.3390/soilsystems10030043 - 17 Mar 2026
Viewed by 1067
Abstract
In permanently submerged coastal wetlands, interactions between biogeochemical processes and microbial communities strongly influence greenhouse gas (GHG) fluxes. To improve our understanding of how redox-driven processes shape GHG dynamics in these ecosystems, we investigated the relationships among iron (Fe) pools, microbial dynamics, and [...] Read more.
In permanently submerged coastal wetlands, interactions between biogeochemical processes and microbial communities strongly influence greenhouse gas (GHG) fluxes. To improve our understanding of how redox-driven processes shape GHG dynamics in these ecosystems, we investigated the relationships among iron (Fe) pools, microbial dynamics, and the potential GHG production in subaqueous soils from an interdunal wetland in San Vitale Park (Italy), permanently submerged and affected by seasonal oscillations of the saline water table. Two subaqueous soil columns (WAS-2 and WAS-4), collected from similar settings, were analyzed. Surface layers of WAS-4 showed higher salinity and carbonate content, whereas WAS-2 was characterized by overall higher Fe concentrations. Distinct vertical distributions of organic matter and sulfur (S) were shown along depth. Laboratory incubations revealed that nitrous oxide (N2O) production was up to ten times higher in WAS-2 than in WAS-4, with peaks in the top 13–14 cm, consistent with more active nitrification-denitrification in surface layers. Methane (CH4) and carbon dioxide (CO2) fluxes decreased with depth, reflecting reduced availability of labile carbon. Methanomicrobiales dominated CH4-producing layers, indicating hydrogenotrophic methanogenesis, while amoA-carrying Nitrosomonadales and Thaumarchaeota, occurred in shallow, organic-rich layers where ammonia supported nitrification and denitrification. Denitrifiers mainly belonged to α- and β-Proteobacteria, consistent with their direct contribution to N2O peaks. Spearman’s correlations showed N2O positively correlated to sulfur and labile carbon (C), supporting denitrification under moderately reducing conditions. CH4 and CO2 positively correlated with organic C (Corg), total nitrogen (TN), and reactive Fe forms, reflecting redox-mediated microbial respiration and methanogenesis. Trace elements (B, Cr, Cu, Ni) acted as micronutrients or inhibitors depending on concentration. Canonical correspondence analysis indicated depth-structured links among gas fluxes, soil chemistry (Corg, TN, S/C, CaCO3, P), and microbial distributions: surface layers, rich in labile C and nutrients, supported active bacteria and archaea involved in decomposition, nitrification, and denitrification, whereas deeper layers hosted oligotrophic archaea adapted to inorganic substrates. Overall, Fe pools appeared to be associated with soil processes relevant to GHG dynamics, although the extent of their regulatory role remains uncertain due to potential alterations of redox-sensitive Fe fractions during sample handling. These results contribute to broader efforts to predict GHG emissions in submerged wetland soils by linking redox stratification, inorganic chemistry, and microbial functional groups. Full article
(This article belongs to the Special Issue Microbial Community Structure and Function in Soils)
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18 pages, 1098 KB  
Review
Optimizing Nitrogen Fertilization in Potato (Solanum tuberosum L.) Cultivation: A Review Regarding Inhibitor Use, Multifaceted Assessment Indicators, and Pathways to Sustainable Intensification
by Myrto Chatzitriantafyllou, Panteleimon Stavropoulos, Stavroula Kallergi, Antonios Mavroeidis, Ioannis Roussis, Stella Karydogianni, Dimitrios Bilalis and Ioanna Kakabouki
Appl. Sci. 2026, 16(5), 2565; https://doi.org/10.3390/app16052565 - 7 Mar 2026
Viewed by 1151
Abstract
Potato (Solanum tuberosum L.), the world’s fourth most significant food crop, faces a critical sustainability challenge: meeting escalating global demand while mitigating the substantial environmental footprint of its production. Potato exhibits high nitrogen requirements, which makes conventional fertilization significantly inefficient, with nitrogen [...] Read more.
Potato (Solanum tuberosum L.), the world’s fourth most significant food crop, faces a critical sustainability challenge: meeting escalating global demand while mitigating the substantial environmental footprint of its production. Potato exhibits high nitrogen requirements, which makes conventional fertilization significantly inefficient, with nitrogen use efficiency (NUE) being below 40%, contributing to severe environmental losses, including nitrate leaching and nitrous oxide emissions. In this comprehensive review, global research is examined regarding enhanced-efficiency nitrogen fertilizers, such as nitrification inhibitors (NIs), urease inhibitors (UIs), and slow-released fertilizers, which promote a pivotal strategy for sustainable potato cultivation. An extensive analysis is provided exploring the biochemical mechanisms of these inhibitors, their complex interactions with potato physiology, and also their impact on tuber yield, quality, and environmental footprint. These insights are combined with sustainable strategies to optimize nitrogen fertilization in potato cropping systems. Lastly, essential knowledge gaps, such as ongoing soil-health impacts and climate-change interactions, are underlined, and future directions of research are proposed to advance inhibitor utilization on potato production. Full article
(This article belongs to the Special Issue Crop Yield and Nutrient Use Efficiency)
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15 pages, 318 KB  
Review
Calcium Cyanamide as an Alternative Nitrogen Fertilizer: A Comprehensive Review of Its Agronomic and Environmental Impacts
by Mzwakhile Petros Zakhe Simelane, Puffy Soundy and Martin Makgose Maboko
Plants 2026, 15(5), 673; https://doi.org/10.3390/plants15050673 - 24 Feb 2026
Viewed by 1096
Abstract
Calcium cyanamide (CaCN2), commercially known as Perlka®, is re-emerging as a multifunctional nitrogen (N) fertilizer with significant agronomic and environmental advantages. Composed of 19.8% nitrogen and 50% calcium oxide (CaO), CaCN2 not only supplies slow-release nitrogen but also [...] Read more.
Calcium cyanamide (CaCN2), commercially known as Perlka®, is re-emerging as a multifunctional nitrogen (N) fertilizer with significant agronomic and environmental advantages. Composed of 19.8% nitrogen and 50% calcium oxide (CaO), CaCN2 not only supplies slow-release nitrogen but also acts as a liming agent, improving soil pH and structure. Its transformation pathway: cyanamide → urea → ammonium → nitrate—ensures a gradual nitrogen release that aligns with crop demand, enhances nitrogen use efficiency, and minimizes nitrate leaching and nitrous oxide emissions. Additionally, the presence of dicyandiamide, a known nitrification inhibitor, further stabilizes nitrogen in the soil. Field studies across diverse cropping systems, including curly endive and short-day onions, have demonstrated that CaCN2 improves yield, crop quality, and soil health. In onions, preplant application of 80 kg ha−1 N from CaCN2 increased bulb yield by up to 18%, enhanced phytochemical content (e.g., phenolics and flavonoids), and reduced nitrate leaching by over 40% compared to urea and limestone ammonium nitrate (LAN). In curly endive, CaCN2 significantly improved ascorbic acid, total soluble solids, and phenolic content, particularly in fall-grown crops, while reducing nitrate accumulation and improving physiological and recovery efficiency of applied nitrogen. Beyond its role as a nutrient supplier, CaCN2 exhibits biocidal properties that suppress soil-borne pathogens such as Sclerotinia and Plasmodiophora brassicae, reduce weed pressure, and stimulate beneficial microbial activity. Its high calcium content also addresses physiological disorders linked to calcium deficiency, such as tip-burn and blossom-end rot. However, proper application timing and dosage are critical to avoid phytotoxicity, especially in sensitive crops. This review synthesizes current knowledge on CaCN2’s chemical behavior, agronomic performance, and environmental implications, and identifies research gaps to guide its optimized use in climate-smart and resource-efficient agriculture. Full article
36 pages, 2321 KB  
Review
Landscape Determinants of Nitrogen Leaching Risk: Mechanisms, Impacts, and Mitigation Strategies
by Bonface O. Manono, Jacinta M. Kimiti and Damaris K. Musyoka
Nitrogen 2026, 7(1), 20; https://doi.org/10.3390/nitrogen7010020 - 5 Feb 2026
Cited by 8 | Viewed by 2781
Abstract
Nitrogen leaching from land and farms is a major global issue that pollutes water, damages ecosystems, and accelerates climate change. This review synthesizes evidence from the literature on how interactions among landscape characteristics, sources of nitrogen input, and temporal dynamics shape leaching vulnerability. [...] Read more.
Nitrogen leaching from land and farms is a major global issue that pollutes water, damages ecosystems, and accelerates climate change. This review synthesizes evidence from the literature on how interactions among landscape characteristics, sources of nitrogen input, and temporal dynamics shape leaching vulnerability. It identifies conditions under which nitrogen is most likely to be transported through soil systems into aquatic environments. This review reveals that leaching vulnerability is strongly conditioned by soil hydraulic properties and topographic position. Coarse-textured upland soils exhibit substantially greater nitrate mobilization than finer-textured, hydrologically buffered lowland soils. Fertilizer formulation and application timing further modulate loss potential, with late-season mineral nitrogen inputs disproportionately contributing to subsurface export relative to demand-synchronized applications. Most of the nitrogen leaching occurs outside the active growing period, when vegetative uptake is suppressed and drainage intensity is highest. Farmers can lower nitrate runoff by using targeted fertilization, cover crops, and nitrification inhibitors, while landscape-scale features like controlled drainage and vegetative buffers provide additional downstream filtration. The effectiveness of regulatory approaches is amplified when aligned with economic incentives and regionally calibrated nutrient thresholds. Advances in high-resolution observation platforms and process-based predictive tools offer new capacity for anticipatory management, although widespread deployment is limited by financial and institutional constraints. Collectively, these insights support the development of more targeted and sustainable nitrogen management strategies. Full article
(This article belongs to the Special Issue Nitrogen Uptake and Loss in Agroecosystems)
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16 pages, 1529 KB  
Article
Dynamics of Soil CH4 and CO2 Fluxes from Cattle Urine with and Without a Nitrification Inhibitor, and Dung Deposited onto a UK Grassland Soil
by Jerry Celumusa Dlamini, David Chadwick and Laura Maritza Cardenas
Methane 2026, 5(1), 4; https://doi.org/10.3390/methane5010004 - 19 Jan 2026
Cited by 1 | Viewed by 992
Abstract
Food production systems associated with livestock management are significant sources of greenhouse gases (GHGs). Livestock excreta are one of the primary sources of GHG emissions from grazing livestock. Against this context, a field experiment was established in a UK grassland to establish the [...] Read more.
Food production systems associated with livestock management are significant sources of greenhouse gases (GHGs). Livestock excreta are one of the primary sources of GHG emissions from grazing livestock. Against this context, a field experiment was established in a UK grassland to establish the extent of soil methane (CH4), carbon dioxide (CO2), andN2O fluxes upon the deposition of (i) cattle urine (U), (ii) urine + dicyandiamide (DCD) (U + DCD), (iii) artificial urine (AU), and dung (D), and compared with a (iv) control, where neither urine nor dung was applied. Excreta applications were made at three experimental periods during the grazing season: early-, mid-, and late-season. Soil N2O emissions data have been published already by co-authors; hence, this paper summarizes the emissions of soil-borne CH4 and CO2 emissions, and explores in particular, the effects of the addition of DCD, a nitrification inhibitor used to reduce direct and indirect N2O emissions from urine patches, on these (carbon) C-GHGs. Soil moisture (p = 0.47), soil temperature (p = 0.51), and nitrate (NO3) (p = 0.049) and ammonium (NH4+) (p = 0.66) availability, and C (p = 0.54) addition were key controls of both soil CH4 and CO2 emissions. The dung treatment stimulated the production and subsequent emissions of soil CH4 and CO2, a significantly high net CH4 and CO2-based global warming potential (GWP). The findings of the current study lay a foundation for an in-depth understanding of the magnitude and dynamics of soil-borne CH4 and CO2 upon urine and dung deposition during three different seasons. This study implies that the use of DCD may have the potential to reduce carbon-based GHGs from the urine and dung of grazing animals. Full article
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16 pages, 2448 KB  
Article
Synergistic Biochar–NBPT–DCD Coating Modulates Nitrogen Dynamics, Mitigates Leaching, and Enhances Yield and Quality of Choy Sum in Sustainable Vegetable Production
by Lixin Lin, Yang Tang, Huang Li, Haili Lv, Bangyu Huang, Haibin Chen and Jianjun Du
Sustainability 2026, 18(1), 383; https://doi.org/10.3390/su18010383 - 30 Dec 2025
Viewed by 1070
Abstract
Conventional urea nitrogen (N) fertilizers are characterized by low use efficiency, resulting in substantial economic losses and environmental degradation. To address this issue, we developed a novel carbon-based stabilized coated urea by incorporating biochar, the urease inhibitor NBPT, and the nitrification inhibitor DCD [...] Read more.
Conventional urea nitrogen (N) fertilizers are characterized by low use efficiency, resulting in substantial economic losses and environmental degradation. To address this issue, we developed a novel carbon-based stabilized coated urea by incorporating biochar, the urease inhibitor NBPT, and the nitrification inhibitor DCD through a low-energy in situ coating process. This study evaluated the effects of this fertilizer on N transformation and loss via soil column leaching and ammonia volatilization experiments, as well as its impact on choy sum (Brassica chinensis L.) yield, N use efficiency (NUE), and product quality under field conditions. Results indicated that coatings containing both NBPT and DCD (specifically, formulations with 0.5%NBPT + 1.0%DCD, and 1.0%NBPT + 1.5%DCD) significantly reduced cumulative ammonium-N leaching by 41.5–53.8% and nitrate-N leaching by 45.3–59.4% compared to conventional urea. All coated treatments suppressed ammonia volatilization by over 10%, with the highest inhibition (26.92%) observed in the treatment with 1.0%NBPT + 1.5%DCD. The synergistic coating also modulated key soil enzyme activities involved in N cycling. Field trials demonstrated that the formulations with 0.5%NBPT + 1.0%DCD and 0.5%NBPT + 1.5%DCD increased choy sum yield by 56.1% and 58.1%, respectively, while significantly improving NUE and agronomic efficiency. Moreover, these treatments enhanced vegetable quality by reducing nitrate content and increasing vitamin C and soluble sugar concentrations. In conclusion, this carbon-based stabilized coated urea, which integrates biochar with NBPT and DCD, represents a promising strategy for minimizing N losses, improving NUE, and advancing sustainable vegetable production. Full article
(This article belongs to the Section Sustainable Agriculture)
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18 pages, 1213 KB  
Article
Contrasting Responses of N2O Mitigation to Different Nitrification Inhibitors in Tea Plantation Soils
by Wei Hua, Siyun Niu, Chenguang Zhao, Jie Wang, Xiangde Yang, Yuanzhi Shi and Kang Ni
Horticulturae 2025, 11(12), 1470; https://doi.org/10.3390/horticulturae11121470 - 5 Dec 2025
Viewed by 722
Abstract
Tea plantations are a hot-spot source of nitrous oxide (N2O) emissions in the agricultural system. Using nitrification inhibitors (NIs) is a promising way to mitigate agricultural N2O emissions and has been widely tested in many croplands. However, the efficiency [...] Read more.
Tea plantations are a hot-spot source of nitrous oxide (N2O) emissions in the agricultural system. Using nitrification inhibitors (NIs) is a promising way to mitigate agricultural N2O emissions and has been widely tested in many croplands. However, the efficiency of different NIs and whether there are soil-specific effects are still unclear in tea plantations with typical acidic soil conditions. This study evaluated the effects of three widely used NIs, i.e., dicyandiamide (DCD), 3,4-dimethylpyrazole phosphate (DMPP), and 2-chloro-6-(trichloromethyl) pyridine (Nitrapyrin), through a lab incubation trial, on the nitrification suppression, N2O emissions, and ammonia-oxidizing microbial communities in two tea plantation soils with contrasting physicochemical properties (pH and texture). During the 50-day incubation, the soil with a higher pH and coarse texture (TA) exhibited a four-times-higher apparent nitrification ratio (ANR) than the more acidic and clay soil (HZ). Nitrification inhibitor addition resulted in about a 60% and 80% reduction in the ANR in HZ and TA soils, respectively. During the entire incubation, ammonium sulfate (N) addition without NIs emitted N2O at 64.1 ± 1.2 and 61.5 ± 0.4 μg N kg−1 (mean ± standard deviation, and the same in the following text) in the HZ and TA soils, respectively. Compared with the N alone, the N2O mitigation efficiency of DCD, DMPP, and Nitrapyrin was 38.3% ± 0.4% (standard deviation), 33.8% ± 0.99%, and 36.5% ± 0.59% in the HZ soil and 94.1% ± 0.39%, 52.8% ± 1.05%, and 95.6% ± 0.65% in the TA soil, respectively. Nitrapyrin more effectively suppressed both ammonia-oxidizing archaeal (AOA) and ammonia-oxidizing bacterial (AOB) abundance, particularly in the acidic soil (HZ), where ammonia-oxidizing archaea dominate nitrification. These results revealed the pivotal role of soil properties in controlling NI efficiency and highlighted Nitrapyrin as a potential superior nitrification inhibitor for N2O mitigation under the tested conditions in this study. Full article
(This article belongs to the Special Issue Sustainable Soil Management for Tea Plantations)
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37 pages, 4377 KB  
Review
Sustainable Approaches to Agricultural Greenhouse Gas Mitigation in the EU: Practices, Mechanisms, and Policy Integration
by Roxana Maria Madjar, Gina Vasile Scăețeanu, Ana-Cornelia Butcaru and Andrei Moț
Sustainability 2025, 17(22), 10228; https://doi.org/10.3390/su172210228 - 15 Nov 2025
Cited by 2 | Viewed by 2110
Abstract
The agricultural sector has a significant impact on the global carbon cycle, contributing substantially to greenhouse gas (GHG) emissions through various practices and processes. This review paper examines the significant role of the agricultural sector in the global carbon cycle, highlighting its substantial [...] Read more.
The agricultural sector has a significant impact on the global carbon cycle, contributing substantially to greenhouse gas (GHG) emissions through various practices and processes. This review paper examines the significant role of the agricultural sector in the global carbon cycle, highlighting its substantial contribution to GHG emissions through diverse practices and processes. The study explores the trends and spatial distribution of agricultural GHG emissions at both the global level and within the European Union (EU). Emphasis is placed on the principal gases released by this sector—methane (CH4), nitrous oxide (N2O), and carbon dioxide (CO2)—with detailed attention to their sources, levels, environmental impacts, and key strategies to mitigate and control their effects, based on the latest scientific data. The paper further investigates emissions originating from livestock production, along with mitigation approaches including feed additives, selective breeding, and improved manure management techniques. Soil-derived emissions, particularly N2O and CO2 resulting from fertilizer application and microbial activity, are thoroughly explored. Additionally, the influence of various agricultural practices such as tillage, crop rotation, and fertilization on emission levels is analyzed, supported by updated data from recent literature. Special focus is given to the underlying mechanisms that regulate these emissions and the effectiveness of management interventions in reducing their magnitude. The research also evaluates current European legislative measures aimed at lowering agricultural emissions and promoting climate-resilient, sustainable farming systems. Various mitigation strategies—ranging from optimized land and nutrient management to the application of nitrification inhibitors and soil amendments are assessed for both their practical feasibility and long-term impact. Full article
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Review
Technological Innovations in Pasture Fertilization in Brazil—Pathways to Sustainability and High Productivity
by Wagner Sousa Alves, Albert José dos Anjos, Danielle Nascimento Coutinho, Paulo Fortes Neto, Tamara Chagas da Silveira and Karina Guimarães Ribeiro
Grasses 2025, 4(4), 43; https://doi.org/10.3390/grasses4040043 - 25 Oct 2025
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Abstract
Although pastures cover nearly half of Brazil’s agricultural land and form the backbone of national livestock production, they have historically received limited attention regarding management and fertilization, resulting in widespread degradation. Sustainable intensification of these pasture-based systems is therefore essential to meet growing [...] Read more.
Although pastures cover nearly half of Brazil’s agricultural land and form the backbone of national livestock production, they have historically received limited attention regarding management and fertilization, resulting in widespread degradation. Sustainable intensification of these pasture-based systems is therefore essential to meet growing global demand for animal products while minimizing environmental impacts. This review highlights recent technological innovations in pasture fertilization in Brazil, with a particular focus on alternative phosphorus sources such as natural reactive phosphates, which offer slow-release nutrients at lower costs compared to conventional fertilizers. Efforts to enhance nitrogen use efficiency through nitrification and urease inhibitors show promise in reducing nutrient losses and greenhouse gas emissions, despite current cost constraints limiting adoption. The integration of grass-legume intercropping, especially with Arachis pintoi, has been shown to enhance forage quality and system persistence when appropriately managed. Moreover, plant growth-promoting microorganisms emerge as sustainable biotechnological tools for restoring degraded pastures and boosting forage productivity without adverse environmental consequences. Properly treated agro-industrial residues also present a viable nutrient source for pastures, provided environmental regulations are strictly followed to prevent pollution. Together, these innovations offer a comprehensive framework for enhancing the productivity and sustainability of Brazilian livestock systems, highlighting the pressing need for continued research and the adoption of advanced fertilization strategies. Full article
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