生态环境学报2025,Vol.34Issue(10):1579-1587,9.DOI:10.16258/j.cnki.1674-5906.2025.10.008
北京城区冬季大气氨浓度、来源及启示
Atmospheric Ammonia Concentrations,Source Apportionment,and Implications during Winter in the Urban Area of Beijing
摘要
Abstract
Ammonia(NH3),the only major alkaline gas in the atmosphere,plays a crucial role in the formation of secondary inorganic aerosols,such as ammonium nitrate and ammonium sulfate,through neutralization with acidic precursors(e.g.SO2 and NOx).These aerosols can contribute up to 50%of the PM2.5 mass concentration in urban China,thus making NH3 a key component in the formation of air pollution.Unlike SO2 and NOx,which have been substantially reduced in China since 2013 owing to stringent emission control policies,NH3 concentrations have remained stable or have even increased in some urban areas.This trend challenges the effectiveness of current pollution mitigation efforts and highlights the importance of identifying and managing NH3 sources,particularly in cities where fine particulate matter pollution remains a persistent health and environmental concern.Although agricultural activities,particularly fertilizer application and livestock,are recognized as the dominant sources of NH3 emissions at the national scale,recent studies suggest that fossil fuel combustion,especially vehicular traffic,is increasingly important in densely populated urban areas.Recently,the relative importance of agricultural and non-agricultural sources of NH3 emissions has remained a subject of ongoing debate,particularly in urban areas.While non-agricultural sources may account for a relatively minor share of total NH3 emissions at regional or broader scales,they can exert a disproportionately significant influence on PM2.5 formation,particularly in densely populated metropolitan areas with high traffic intensity.However,these non-agricultural sources are often underrepresented or entirely omitted in regional emission inventories due to a lack of measurement data,making it difficult to support effective policy interventions for their reduction.This study addresses this knowledge gap by integrating ambient NH3 concentration measurements with stable nitrogen isotope(δ15N-NH3)analysis to apportion emission sources across multiple urban microenvironments in Beijing during winter.Ambient NH3 was measured using ALPHA passive samplers deployed at 17 strategically selected sites across Beijing,comprising 12 roadside locations along major transportation corridors and five non-roadside sites representing diverse urban land-use types,including university campuses,forest parks and peri-urban agricultural areas.Weekly measurements were conducted from December 2016 to January 2017,and five samples were collected for each measurement.For three representative weeks,the collected NH3 samples were further analyzed for δ15N values using a BrO⁻ oxidation-NH2OH reduction protocol coupled with PT-IRMS detection.Ambient NH3 concentrations during the study period ranged from 2.1 μg·m-3 to 32.9 μg·m-3,with an overall mean of(14.3±0.8)μg·m-3.The δ15N-NH3 values ranged between-40‰ and-25‰,with a mean of-32.8‰±1.1‰.Roadside sites consistently exhibited higher NH3 concentrations and less negative δ15N values than non-roadside sites,indicating a stronger influence from isotopically enriched sources,such as traffic exhaust.Isotope mixing model simulations,informed by the measured δ15N values of NH3 and isotopic signature values of major emission sources,suggested that non-agricultural sources contributed approximately 54%±14%of total NH3 in the urban atmosphere during the monitoring period,with a range of 32%‒74%.At roadside locations,the non-agricultural contribution was even higher,reaching 74%at certain sites.These results demonstrate a clear spatial pattern of NH3 pollution,where proximity to major roadways significantly increases both the concentration and isotopic enrichment of atmospheric NH3.In contrast,two campus sites(i.e.China Agricultural University and Beijing Normal University),dominated by residential,administrative,and educational activities,are subject to limited and low-intensity anthropogenic NH3 emissions.Hence,relatively low NH3 concentrations and δ15N values were observed in this study.Forest park sites(i.e.,Olympic Forest Park and Baiwangshan Forest Park)showed the lowest NH3 levels,likely due to NH3 uptake by vegetation and minimal direct emissions from these areas.The agricultural site located on Beijing's urban fringe had low NH3 levels,which was consistent with the suppressed agricultural activity during the cold season.The δ15N approach provides several methodological advantages for the source apportionment of atmospheric NH3.Unlike chemical speciation alone,isotopic measurements offer source-specific fingerprints that can be used to resolve overlapping emission contributions,particularly in complex urban environments such as Beijing.Although our observations provided dense spatial coverage,it is important to consider the potential isotopic fractionation associated with diffusion sampling.In this study,we recognized that the parameter f plays a critical role in equilibrium isotopic fractionation during the gas-to-particle conversion of nitrogen.Therefore,we adopted the expected relationship between the initial δ15N-NH3 and varying f values to mitigate the influence of isotopic fractionation.For source apportionment purposes,NH3 and NH4+should be treated as a unified species(i.e.,NHx),with full consideration given to isotopic fractionation occurring during the NH3-NH4+conversion.However,the low temporal resolution of our weekly measurements may obscure short-term variations in δ15N associated with NHx partitioning and the influence of atmospheric conditions on their kinetics of uptake.This highlights the need for future studies to implement synchronized δ15N measurements of gaseous NH3 and particulate NH4⁺,along with higher-resolution monitoring,to enable more reliable source apportionment using refined stable isotope techniques.Our findings underscore the increasingly prominent role of non-agricultural NH3 emissions,particularly traffic-derived emissions,in the atmospheric nitrogen budget and PM2.5 formation in Chinese megacities.This aligns with national trends in vehicle ownership,which have risen dramatically over the past decade,leading to increased exhaust emissions.Given the health hazards posed by sustained dependence on fossil fuels and the shift toward sustainable development,a transition in the energy sector is both urgent and inevitable.In conclusion,this study provides isotopic evidence that non-agricultural sources,particularly vehicular emissions,substantially contribute to urban atmospheric NH3 concentrations in Beijing during winter.The elevated NH3 concentrations and δ15N-NH3 values at roadside sites highlight the growing influence of traffic emissions and suggest that urban NH3 pollution can no longer be attributed solely to agricultural activities.To effectively address urban NH3 pollution,future policies should broaden the current agricultural-focused control strategies by incorporating non-agricultural NH3 emissions,e.g.transportation and waste management sectors.Moreover,integrating isotope-based field monitoring with dynamic atmospheric transport models may provide better constraints on urban NH3 emission inventories and support the co-design of pollution control and public health protection strategies.Such efforts are essential for meeting China's dual objectives of air quality improvement and sustainable urban development in the context of its national carbon neutrality targets.关键词
氨气/城区/氮同位素/来源解析/空气质量Key words
ammonia/urban area/nitrogen isotopes/source apportionment/air quality分类
资源环境引用本文复制引用
张洋洋,刘学军..北京城区冬季大气氨浓度、来源及启示[J].生态环境学报,2025,34(10):1579-1587,9.基金项目
国家自然科学基金项目(42107111) (42107111)
