Research progress on the monitoring methods of atmospheric nitrogen deposition

doi:10.13287/j.1001-9332.201910.008

Abstract

Abstract: As an important component of global nitrogen (N) biogeochemical cycle, atmospheric N deposition refers to the removal process of reactive N, including oxidized N (NO_y) and reduced N (NH_x), from the atmosphere to earth surface through dry and wet deposition. Nitrogen deposition can exert important impacts on the structure and functioning of both terrestrial and aquatic ecosystems. Increasing N deposition poses a potential threat to natural ecosystems and human health. It is a challenge to accurately monitor the composition and flux of dry and wet N deposition in different ecosystems, using a unified technology. Here, we reviewed the research progress on monitoring methods of dry and wet N deposition in China and aboard, including micrometeorology, inferential method, model estimation, surrogate surface, precipitation collection, and ion exchange resin methods. We further discussed the advantages and disadvantages of each method in terms of its applications at regional, national, and global scales. This review would provide a methodological support to establish national monitoring network for atmospheric N deposition.

WU Yu-feng, GAO Xiao-peng, GUI Dong-wei, LIU Xue-jun. Research progress on the monitoring methods of atmospheric nitrogen deposition[J]. Chinese Journal of Applied Ecology, 2019, 30(10): 3605-3614.

References

[1] Ackerman DE, Chen X, Millet DB. Global Nitrogen Deposition (2°×2.5° Grid Resolution) Simulated with GEOS-Chem for 1984-1986, 1994-1996, 2004-2006, and 2014-2016 [EB/OL]. (2018-10-10) [2019-07-01]. https://conservancy.umn.edu/handle/11299/197613
[2] Fowler D, Coyle M, Skiba U, et al. The global nitrogen cycle in the twenty-first century. Philosophical Transactions of the Royal Society B, 2013, 368: 20130164
[3] Bowman WD, Cleveland CC, Halada L, et al. Negative impact of nitrogen deposition on soil buffering capacity. Nature Geoscience, 2008, 1: 767-770
[4] Alard D, Dorland E, Dupre C, et al. Impact of nitrogen deposition on species richness of calcareous grasslands in Europe: Some preliminary results// Hicks WK, Whitfield WJ, Bealey MA, eds. Nitrogen Deposition and Natura 2000. New York: COST, 2000: 155-161
[5] Zhang X-F (张修峰). Atmospheric nitrogen wet deposition and its effects on wetland water environment of Shanghai area. Chinese Journal of Applied Ecology (应用生态学报), 2006, 17(6): 1099-1102 (in Chinese)
[6] Zhou G-Y (周国逸), Yan J-H (闫俊华). The influences of regional atmospheric precipitation characteristics and its element inputs on the existence and development of Dinghushan forest ecosystems. Acta Ecologica Sinica (生态学报), 2000, 21(12): 2002-2012 (in Chinese)
[7] Liu X-J (刘学军), Zhang F-S (张福锁). Spatial and temporal variation of atmospheric nitrogen deposition in North China Plain. Acta Ecologica Sinica (生态学报), 2006, 26(6): 1633-1639 (in Chinese)
[8] Liu X-J (刘学军), Zhang F-S (张福锁). Nutrient from environment and its effect in nutrient resources management of ecosystems: A case study on atmospheric nitrogen deposition. Arid Zone Research (干旱区研究), 2009, 26(2): 306-311 (in Chinese)
[9] Lu X , Mao Q , Gilliam FS, et al. Nitrogen deposition contributes to soil acidification in tropical ecosystems. Global Change Biology, 2014, 20: 3790-3801
[10] Lu X, Mao Q, Mo J, et al. Divergent responses of soil buffering capacity to long-term N deposition in three typical tropical forests with different land-use history. Environmental Science & Technology, 2015, 49: 4072-4080
[11] Lu X, Vitousek PM, Mao Q, et al. Plant acclimation to long-term high nitrogen deposition in an N-rich tropical forest. Proceedings of the National Academy of Sciences of the United States of America, 2018, 115: 5187-5192
[12] Zhu J, He N, Wang Q, et al. The composition, spatial patterns, and influencing factors of atmospheric wet nitrogen deposition in Chinese terrestrial ecosystems. Science of the Total Environment, 2015, 511: 777-785
[13] Zhao Y, Zhang L, Chen Y, et al. Atmospheric nitrogen deposition to China: A model analysis on nitrogen bud-get and critical load exceedance. Atmospheric Environment, 2017, 153: 32-40
[14] Liu X, Duan L, Mo J, et al. Nitrogen deposition and its ecological impact in China: An overview. Environmental Pollution, 2011, 159: 2251-2264
[15] Klopatek JM, Barry MJ, Johnson DW. Potential canopy interception of nitrogen in the Pacific Northwest, USA. Forest Ecology and Management, 2006, 234: 344-354
[16] Ferm M, Svanberg PA. Cost-efficient techniques for urban- and background measurements of SO₂ and NO₂. Atmospheric Environment, 1998, 32: 1377-1381
[17] Tang YS, Cape JN, Sutton MA. Development and types of passive samplers for monitoring atmospheric NO₂ and NH₃ concentrations. The Scientific World Journal, 2001, 1: 513-529
[18] Roadman MJ, Scudlark JR, Meisinger JJ, et al.Validation of Ogawa passive samplers for the determination of gaseous ammonia concentrations in agricultural settings. Atmospheric Environment, 2003, 37: 2317-2325
[19] Holland EA, Braswell BH, Sulzman J, et al. Nitrogen deposition onto the United States and western Europe: Synthesis of observations and models. Ecological Applications, 2005, 15: 38-57
[20] Wesely ML. Parameterization of surface resistances to gaseous dry deposition in regional-scale numerical models. Atmospheric Environment, 2007, 41: 52-63
[21] Singles RJ, Sutton MA, Weston KJ. A multi-layer model to describe the atmospheric transport and deposition of ammonia in Great Britain. Atmospheric Environment, 1998, 32: 393-399
[22] Zhang Q (张琪), Chang M (常鸣), Wang X-M (王雪梅), et al. Advances in nitrogen deposition observation in China and its application in the Pearl River Delta. China Environmental Science (中国环境科学), 2017, 37(12): 4401-4416 (in Chinese)
[23] Fan J-L (樊建凌), Hu Z-Y (胡正义), Zhou J (周静), et al. Comparative study on the observation of atmospheric nitrogen deposition in a forestland. Chinese Environmental Science (中国环境科学), 2013, 33(5): 786-792 (in Chinese)
[24] Watt SA, Wagner-Riddle C, Edwards G, et al. Evaluating a flux-gradient approach for flux and deposition velocity of nitrogen dioxide over short-grass surfaces. Atmospheric Environment, 2004, 38: 2619-2626
[25] Businger JA. Evaluation of the accuracy with which dry deposition can be measured with current micrometeorological techniques. Journal of Climate and Applied Meteorology, 1986, 25: 1100-1124
[26] Hicks BB. Measuring dry deposition: A re-assessment of the state of the art. Water, Air and Soil pollution, 1986, 30: 75-90
[27] Cornell SE, Jickells TD, Cape JN, et al. Organic nitrogen deposition on land and coastal environments: A review of methods and data. Atmospheric Environment, 2003, 37: 2173-2191
[28] Song H-H (宋欢欢), Jiang C-M (姜春明), Yu W-T (宇万太). Basic features and monitoring methodologies of atmospheric nitrogen deposition. Chinese Journal of Applied Ecology (应用生态学报), 2014, 25(3): 599-610 (in Chinese)
[29] Chen N-W (陈能汪), Hong H-S (洪华生), Xiao J (肖健), et al. Dry deposition of atmospheric nitrogen to Jiulong River watershed in southeast China. Acta Ecologica Sinica (生态学报), 2006, 26(8): 2602-2607 (in Chinese)
[30] Chen XY, Mulder J. Atmospheric deposition of nitrogen at five subtropical forested sites in South China. Science of the Total Environment, 2007, 378: 317-330
[31] Coble AA, Hart SC. The significance of atmospheric nutrient inputs and canopy interception of precipitation during ecosystem development in Pion-juniper woodlands of the southwestern USA. Journal of Arid Environments, 2013, 98: 79-87
[32] Zhang J, Kang RH, Zhao B, et al. Monitoring nitrogen deposition on temperate grassland in Inner Mongolia. Environmental Science, 2013, 34: 3552
[33] Tang YS, Simmons I, Dijk NV, et al. European scale application of atmospheric reactive nitrogen measurements in a low-cost approach to infer dry deposition fluxes. Agriculture, Ecosystems & Environment, 2009, 133: 183-195
[34] Yan W-J (颜文娟), Shi K (史锟), Liu X- J (刘学军), et al. Atmospheric deposition of reactive nitrogen in agricultural zone, Lvshunkou, Dalian. Environmental Chemistry (环境化学), 2014, 33(7): 1180-1186 (in Chinese)
[35] Zhang Y, Xu W, Zhang W, et al. Atmospheric deposition of inorganic nitrogen in a semi-arid grassland of Inner Mongolia, China. Journal of Arid Land, 2017, 9: 810-822
[36] Liang T, Tong Y, Liu X, et al. High nitrogen deposition in an agricultural ecosystem of Shaanxi, China. Environmental Science & Pollution Research, 2016, 23: 13210-13221
[37] Brook JR, Di-Giovanni F, Padro J, et al. Description and evaluation of a model of deposition velocities for routine estimates of air pollutant dry deposition over North America. Part I: Model development. Atmospheric Environment, 1999, 33: 5037-5051
[38] Jonson JE, Bartnicki J, Olendrzynski K, et al. EMEP Eulerian model for atmospheric transport and deposition of nitrogen species over Europe. Environmental Pollution, 1998, 102: 289-298
[39] Park SU, Lee YH, Lee EH. Estimation of nitrogen dry deposition in South Korea. Atmospheric Environment, 2002, 36: 4951-4964
[40] Lu CQ, Tian HQ. Spatial and temporal patterns of nitrogen deposition in China: Synthesis of observational data. Journal of Geophysical Research: Atmospheres, 2007, 112: 229-238
[41] Dentener F, Drevet J, Lamarque JF, et al. Nitrogen and sulfur deposition on regional and global scales: A multimodel evaluation. Global Biogeochemical Cycles, 2006, 20: 16615-16615
[42] Vet R, Artz RS, Carou S, et al. A global assessment of precipitation chemistry and deposition of sulfur, nitrogen, sea salt, base cations, organic acids, acidity and pH, and phosphorus. Atmospheric Environment, 2014, 93: 93-100
[43] Xu W, Luo XS, Pan YP, et al. Quantifying atmospheric nitrogen deposition through a nationwide monitoring network across China. Atmospheric Chemistry and Physics, 2015, 15: 18365-18405
[44] Wei Y (魏样), Tong Y-A (同延安), Duan M (段敏), et al. Atmospheric dry and wet nitrogen deposition in typical agricultural areas of North Shaanxi. Chinese Journal of Applied Ecology (应用生态学报), 2010, 21(1): 255-259 (in Chinese)
[45] Yu W-T (宇万太), Ma Q (马强), Zhang L (张璐), et al. Dynamic changes of nitrogen in precipitation in lower reach of Liaohe River Plain. Chinese Journal of Ecology (生态学杂志), 2008, 27(1): 33-37 (in Chinese)
[46] Liu XJ, Ju XT, Zhang Y, et al. Nitrogen deposition in agroecosystems in the Beijing area. Agriculture, Ecosystems & Environment, 2006, 113: 370-377
[47] Sheng WP, Yu GR, Jiang CM, et al. Monitoring nitrogen deposition in typical forest ecosystems along a large transect in China. Environmental Monitoring and Assessment, 2013, 185: 833-844
[48] Clow DW, Roop HA, Nanus L, et al. Spatial patterns of atmospheric deposition of nitrogen and sulfur using ion-exchange resin collectors in Rocky Mountain National Park, USA. Atmospheric Environment, 2015, 101: 149-157
[49] Hsu YM, Bytnerowicz A, Fenn ME, et al. Atmospheric dry deposition of sulfur and nitrogen in the Athabasca Oil Sands Region, Alberta, Canada. Science of the Total Environment, 2016, 568: 285-295
[50] Nowlan CR, Martin RV, Philip S, et al. Global dry deposition of nitrogen dioxide and sulfur dioxide inferred from space-based measurements. Global Biogeochemical Cycles, 2015, 28: 1025-1043
[51] Chen MM, Hong J, Zheng G, et al. Estimating NO₂ dry deposition using satellite data in eastern China. International Journal for Remote Sensing, 2013, 34: 2548-2565
[52] Leue C, Wenig M, Wagner T, et al. Quantitative analysis of NOx emissions from Global Ozone Monitoring Experiment satellite image sequences. Journal of Geophysical Research Atmospheres, 2001, 106: 5493-5505
[53] Jia Y, Yu G, Gao Y, et al. Global inorganic nitrogen dry deposition inferred from ground- and space-based measurements. Scientific Reports, 2016, 6: 19810
[54] Mehlert S, Schmidt G, Russow R. Measuring of the integral airborne nitrogen-input into a soil-plant system by the ¹⁵N-isotope dilution method. Isotopes in Environmental and Health Studies, 1995, 31: 377-383
[55] Russow R, Bhme FB. Determination of the total nitrogen deposition by the ¹⁵N isotope dilution method and problems in extrapolating results to field scale. Geoderma, 2005, 127: 62-70
[56] He C, Liu X, Fangmeier A, et al. Quantifying the total airborne nitrogen input into agroecosystems in the North China Plain. Agriculture, Ecosystems & Environment, 2007, 121: 395-400
[57] Russow RW, Bohme F, Neue HU, et al. A new approach to determine the total airborne N input into the soil/plant system using ¹⁵N isotope dilution (ITNI): Results for agricultural areas in Central Germany. The Scientific World Journal, 2001, 1: 255-260