Side-by-side Chinese-English


张琪1 常鸣2 王雪梅2

(1.中山大学大气科学学院, 广东广州 510275)
(2.暨南大学环境与气候研究院, 广东广州 510632)


【关键词】 大气污染;氮沉降;观测;


【基金资助】 国家重点研发计划资助项目(2017YFC0210103;2017YFC0210105); 国家自然科学基金:青年科学基金项目(41705123); 国家杰出青年科学基金资助项目(41425020); 广东省科技计划项目(2016B050502005);

Advances in nitrogen deposition observation in China and its application in the Pearl River Delta

ZHANG Qi1 CHANG Ming2 WANG Xue-mei2

(1.School of Atmospheric Sciences, Sun Yat-sen university, Guangzhou, China 510275)
(2.Institute for Environmental and Climate Research, Jinan University, Guangzhou, China 510632)

【Abstract】The present study reviewed the methodologies currently applied to atmospheric nitrogen deposition observation in China, as well as analyzed the long-term trend of the nitrogen deposition observed in the Pearl River Delta (PRD) region, South China. The atmospheric nitrogen deposition flux decreased from the southeast coast to the northwest inland, and the ecosystems influencing by more human activities tended to be of higher deposition load. The wet deposition fluxes were in the range of 18–38 kgN/(hm2·a) and 6–78 kgN/(hm2·a) for forest ecosystem and cropland ecosystem, respectively. More specifically in cropland, the fluxes of bulk deposition and dry deposition were respectively 15–133 kgN/(hm2·a) and 54–83 kgN/(hm2·a). And the bulk deposition flux in the urban ecosystem had achieved to 101 kgN/(hm2·a). In the PRD region, the deposition fluxes of total nitrogen and the ratio of NH4+-N/NO3-N were declining in the past years. This could be explained by the industrial structure adjustment and the huge energy consumption accompanied with urban development. In general, the measurements for nitrogen deposition observation in China are becoming more and more diversified, and the results are also becoming more convincing. However, the observation is very scarce in the remote areas and wet deposition and bulk deposition, while the study of dry deposition is still insufficient.

【Keywords】 atmospheric pollution; nitrogen deposition; observation;


【Funds】 National Key Research and Development Program of China (2017YFC0210103; 2017YFC0210105); National Natural Science Foundation of China: Youth Science Fund Project (41705123); National Science Foundation for Distinguished Young Scholars (41425020); Science and Technology Planning Project of Guangdong Province (2016B050502005);

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    [1] Galloway J N, Aber J D, Erisman J W, et al. The Nitrogen Cascade [J]. Bio Science, 2003, 53 (4): 341–356.

    [2] Galloway J N, Dentener F J, Capone D G, et al. Nitrogen Cycles: Past, Present, and Future [M]. London: Royal Horticultural Society, 2004: 153–226.

    [3] Canfield D E, Glazer A N, Falkowski P G. The evolution and future of Earth’s nitrogen cycle [J]. Science, 2010, 330 (6001): 192–196.

    [4] Galloway J N, Townsend A R, Erisman J W, et al. Transformation of the nitrogen cycle: recent trends, questions, and potential solutions [J]. Science, 2008, 320 (5878): 889–892.

    [5] Liu X, Zhang Y, Han W, et al. Enhanced nitrogen deposition over China [J]. Nature, 2013, 494 (7438): 459.

    [6] Yan Z Q, Qi Y C, Dong Y S et al. Effects of changing precipitation regime and increasing nitrogen deposition on key processes of nitrogen cycle in grassland ecosystem [J]. China Environmental Science, 2016, 36 (4): 1189–1197 (in Chinese).

    [7] Hu Z H, Zhang H, Chen S T et al. Effects of simulated nitrogen deposition on N2O and CH4 fluxes of soil in forest belt [J]. China Environmental Science, 2011, 31 (6): 892–897 (in Chinese).

    [8] Guo J H, Liu X J, Zhang Y, et al. Significant Acidification in Major Chinese Croplands [J]. Science, 2010, 327 (5968): 1008.

    [9] Zheng D N, Wang X S, Xie S D et al. Simulation of atmospheric nitrogen deposition in China in 2010 [J]. China Environmental Science, 2014, 34 (5): 1089–1097 (in Chinese).

    [10] Nadim F, Stapcinskaite S, Trahiotis M M, et al. The e ect of precipitation amount and atmospheric concentrations on wet deposition fluxes of oxidized and reduced nitrogen species in Connecticut [J]. Water, Air, and Soil Pollution, 2003, 143 (1–4): 315–335.

    [11] Golden H E, Boyer E W, Brown M G, et al. Simple approaches for measuring dry atmospheric nitrogen deposition to watersheds [J]. Water Resources Research, 2008, 44 (4): 0–2.

    [12] Jia Y, Yu G, Gao Y, et al. Global inorganic nitrogen dry deposition inferred from ground-and space-based measurements [J]. Scientific Reports, 2016, 6 (6): 19810.

    [13] Zhao D, Sun B. Air Pollution and Acid Rain in China [J]. Ambio, 1986, 15 (1): 2–5.

    [14] Ding G A, Xu X B, Wang S F et al. Database from the acid rain network of China meteorological administration and its preliminary analyses [J]. Journal of Applied Meteorological Science, 2004, 15 (s1): 85–94 (in Chinese).

    [15] Tang D, Lydersen E, Seip H M, et al. Integrated Monitoring Program on Acidification of Chinese Terrestrial Systems (Impacts)-A Chinese-Norwegian Cooperation Project [J]. Water, Air, & Soil Pollution, 2001, 130 (1): 1073–1078.

    [16] Liu X J, Zhang F S. Nutrient from Environment and Its Effect in Nutrient Resources Management of Ecosystems——A Case Study on Atmospheric Nitrogen Deposition [J]. Arid Zone Research, 2009, 26 (3): 306–311 (in Chinese).

    [17] Liu X, Duan L, Mo J, et al. Nitrogen deposition and its ecological impact in China: an overview [J]. Environmental Pollution, 2011, 159 (10): 2251.

    [18] Sheng W, Yu G, Jiang C, et al. Monitoring nitrogen deposition in typical forest ecosystems along a large transect in China [J]. Environmental Monitoring & Assessment, 2013, 185 (1): 833–844.

    [19] Liu Y W, Xu-Ri, Wang Y S, et al. Wet deposition of atmospheric inorganic nitrogen at five remote stations on the Tibetan Plateau [J]. Atmospheric Chemistry & Physics, 2015, 15 (20): 11683–11700.

    [20] Wang J F, Zhou K J, Wang X Q et al. Atmospheric nitrogen and phosphorous deposition in Hangjiahu area [J]. China Environmental Science, 2015, 35 (9): 2754–2763 (in Chinese).

    [21] Yu W T, Ma Q, Zhang L et al. Dynamic changes of nitrogen in precipitation in lower reach of Liaohe River Plain [J]. Chinese Journal of Ecology, 2008, 27 (1): 33-37 (in Chinese).

    [22] Sun Z G, Liu J S, Wang J D. Study on Nitrogen Concentration and Deposition Amount in Wet Deposition in Typical Wetland Ecosystem of Sanjiang Plain [J]. Soil and Crop, 2007, 23 (1): 114–119 (in Chinese).

    [23] Li Y Z, Zhu T C, Jiang S C. Nitrogen Deposition in Leymus chinensis Grassland of Songnen Plain [J]. Chinese Journal of Grassland, 2000, 2: 24–27 (in Chinese).

    [24] Zhou G Y, Yan J H. The influences of regional atmospheric precipitation characteristics and its element inputs on the existence and development of Dinghushan forest ecosystems [J]. Acta Ecologica Sinica, 2001, 21 (12): 2002–2012 (in Chinese).

    [25] Wang X Z, Zhu J G, Gao R et al. Dynamics and ecological significance of nitrogen wet-deposition in Taihu Lake region-Taking Changshu Agro-ecological Experiment Station as an example [J]. Chinese Journal of Applied Ecology, 2004, 15 (9): 1616–1620 (in Chinese).

    [26] Song Y Z, Qin B Q, Yang L Y et al. Primary Estimation of Atmospheric Wet Deposition of Nitrogen to Aquatic Ecosystem of Lake Taihu [J]. Journal of Lake Sciences, 2005, 17 (3): 226–230 (in Chinese).

    [27] Zhang Y, Liu X J, Zhang F S et al. Spatial and temporal variation of atmospheric nitrogen deposition in North China Plain [J]. Acta Ecologica Sinica, 2006, 26 (6): 1633–1639 (in Chinese).

    [28] Xie Y X, Zhang S L, Zhao X et al. Seasonal variation patterns of NH4+-N/NO3-N ratio and δ15NH4+ value in rainwater in Yangtze River Delta [J]. Chinese Journal of Applied Ecology, 2008, 19 (9): 2035–2041 (in Chinese).

    [29] Xie Y, Xiong Z, Xing G, et al. Source of nitrogen in wet deposition to a rice agroecosystem at Tai lake region [J]. Atmospheric Environment, 2008, 42 (21): 5182–5192.

    [30] Chen Y, Tang X, Yang S M et al. Atmospheric N wet deposition in Hangzhou region under rice-wheat-vegetable cropping system [J]. Acta Ecologica Sinica, 2009, 29 (11): 6102–6109 (in Chinese).

    [31] Fang Z G, Zhao X F. Dynamic changes of atmospheric nitrogen wet deposition in Qingdao [J]. Journal of Soil and Water Conservation, 2013 (1): 263–266 (in Chinese).

    [32] Fang Z G, Zhao X F. Dynamic changes of atmospheric nitrogen wet deposition in Qingdao [J]. Journal of Soil and Water Conservation, 2013 (1): 263–266 (in Chinese).

    [33] Lü C, Tian H. Spatial and temporal patterns of nitrogen deposition in China: Synthesis of observational data [J]. Journal of Geophysical Research: Atmospheres, 2007, 112 (D22): 229–238.

    [34] Liu D B, Zhang X Y, Ba R X et al. Atmospheric nitrogen deposition in Danjiangkou Reservoir area of Northwest Hubei [J]. Acta Ecologica Sinica, 2015, 35 (10): 3419–3427 (in Chinese).

    [35] Liu T, Yang L Y, Hu Z X et al. Spatial-temporal Features of Atmospheric Deposition of Nitrogen and Phosphorus to the Lake Taihu [J]. The Administration and Technique of Environmental Monitoring, 2012, 24 (6): 20–24 (in Chinese).

    [36] Lin L W, Xiao H L, Liu T L et al. Dynamics of wet atmospheric nitrogen deposition and the relation to acid rain in the northeast suburb of Guangzhou [J]. Ecology and Environmental Sciences, 2013, 2: 293–297 (in Chinese).

    [37] Zhang G Z, Pan Y P, Tian S L et al. Limitations of Passive Sampling Technique of Rainfall Chemistry and Wet Deposition Flux Characterization [J]. Research of Environmental Sciences, 2015, 28 (5): 684–690 (in Chinese).

    [38] Liu X, Ju X, Zhang Y, et al. Nitrogen deposition in agroecosystems in the Beijing area [J]. Agriculture Ecosystems & Environment, 2006, 113 (1–4): 370–377.

    [39] Zong H J, T E J, Niu Q Y et al. The status, constraints and trends of automatic rainfall monitor in our country [J]. Environmental Monitoring in China, 2005, 21 (2): 64–65 (in Chinese).

    [40] Cui Y, Guo W D, Fan X Z et al. Comparison of Collecting Methods of Precipitation Based on the Standard Precipitation Gauge [J]. Environmental Monitoring in China, 2016, 32 (1): 88–93 (in Chinese).

    [41] HJ/T174-2005降雨自动采样器技术要求及检测方法 [S]. (in Chinese).

    [42] GB/T13580. 1-1992大气降水采样和分析方法 [S]. (in Chinese).

    [43] Kochy M, Wilson S D. Nitrogen deposition and forest expansion in the northern Great Plains [J]. Journal of Ecology, 2001, 89 (5): 807–817.

    [44] Johnson D W. Ion exchange resin based soil solution lysimeters and snowmelt solution collectors [J]. Communications in Soil Science and Plant Analysis, 2002, 33 (7/8): 1261–1275.

    [45] Cui Y, Guo W D, Fan X Z et al. Comparison of Collecting Methods of Precipitation Based on the Standard Precipitation Gauge [J]. Environmental Monitoring in China, 2016, 32 (1): 88–93 (in Chinese).

    [46] Zeng M, Yu L F, Zhang Y, et al. Determination of δ15N of ammonium and nitrate in nature waters [J]. Environmental Chemistry, 2013, 8: 1486–1490.

    [47] Baker A R, Weston K, Kelly S D, et al. Dry and wet deposition of nutrients from the tropical Atlantic atmosphere: Links to primary productivity and nitrogen fixation [J]. Deep Sea Research Part I Oceanographic Research Papers, 2007, 54 (10): 1704–1720.

    [48] Wang D X, Zhao P S, Zhang Y X. Monitoring Atmospheric Nitrogen Deposition in Changchun Using Ion Exchange Resin Columns Method [J]. Research of Environmental Sciences, 2010, 23 (8): 1013–1018 (in Chinese).

    [49] Sun S Q, Wang Y J, Wang Y Q et al. Rainfall Process and Nitrogen Input in Three Typical Forests of Jinyun Mountain [J]. Environmental Science, 2014, 35 (3): 1081–1090 (in Chinese).

    [50] He C W, Ren Y F, Wang X K et al. Characteristics of Atmospheric Nitrogen Wet Deposition in Beijing Urban Area [J]. Environmental Science, 2014, 35 (2): 490–494 (in Chinese).

    [51] Li D D, Su Y Q, Zhou T Y et al. Application of ion-exchange resin method on the observation of wet nitrogen deposition fluxes inside and outside Tiantong forest [J]. Journal of East China Normal University(Natural Science), 2015, 6: 117–125 (in Chinese).

    [52] Sheng W P, Yu G R, Fang H J et al. Determination of nitrogen deposition in throughfall using ion-exchange resins: a field test in planted coniferous forest ecosystem at Qianyanzhou [J]. Acta Ecologica Sinica, 2010, 30 (24): 6872–6880 (in Chinese).

    [53] Liu S R. Biogeochemical Cycling Characteristics of Dahurian Larch Plantation Ecosystem [J]. Chinese Journal of Ecology, 1992, 5: 1–6 (in Chinese).

    [54] Ma X H. Effects of rainfall on the nutrient cycling in man-made forests of cunninghamia lanceolata and pinus massoniana [J]. Acta Ecologica Sinica, 1989, 9 (1): 15–20 (in Chinese).

    [55] Huang Z L, Ding M M, Zhang Z P et al. The hydrological processes and nitrogen dynamics in a monsoon evergreen broad-leafed forest of Dinghu Shan [J]. Chinese Journal of Plant Ecology, 1994, 18 (2): 194–199 (in Chinese).

    [56] Fan H B, Su B Q, Lin D X et al. Biogeochemical cycle within ecosystem of Chinses fir plantations Ⅱ: Dynamics of nitrogen deposition [J]. Chinese Journal of Applied and Environmental Biology, 2000, 6 (2): 133–137 (in Chinese).

    [57] Sha L Q, Zheng Z, Feng Z L et al. Biogeochemical cycling of nitrogen at a tropical seasonal rain forest in Xishuangbanna, SW China [J]. Chinese Journal of Plant Ecology, 2002, 26 (6): 689–694 (in Chinese).

    [58] Chen N W, Hong H S, Xiao J et al. Dry deposition of atmospheric nitrogen to Jiulong River watershed in southeast China [J]. Acta Ecologica Sinica, 2006, 26 (8): 2602–2607 (in Chinese).

    [59] Chen N W, Hong H S, Zhang L P. Wet Deposition of Atmospheric Nitrogen in Jiulong River Watershed [J]. Environmental Science, 2008, 29 (1): 38–46 (in Chinese).

    [60] Fan J L, Hu Z Y, Zhou J et al. Comparative study on the observation of atmospheric nitrogen deposition in a forestland [J]. China Environmental Science, 2013, 33 (5): 786–792 (in Chinese).

    [61] Davidson C I, Lindberg S E, Schmidt J A, et al. Dry deposition of sulfate onto surrogate surfaces [J]. Journal of Geophysical Research Atmospheres, 1985, 90 (ND1): 2123–2130.

    [62] Dolske D A, Gatz D F. A field intercomparison of methods for the measurement of particle and gas dry deposition [J]. Journal of Geophysical Research Atmospheres, 1985, 90 (ND1): 2076–2084.

    [63] Davidson C I, Wu Y L. Dry Deposition of Particles and Vapors [M]. Acidic Precipitation. Springer New York, 1990: 103–216.

    [64] Bidleman T F. Atmospheric processes [J]. Environmental Science&Technology, 1988, 22 (4): 361–367.

    [65] Li S X, Cun D G, Gao Y J et al. Mineral nitrogen introuduced into soil by precipitation on Loess dryland [J]. Agricultural Research in the Arid Areas, 1993, s1: 83–92 (in Chinese).

    [66] Zobrist J, Wersin P, Jaques C, et al. Dry deposition measurements using water as a receptor: A chemical approach [J]. Water, Air, & Soil Pollution, 1993, 71 (1): 111–130.

    [67] Hicks B B. Measuring dry deposition: A re-assessment of the state of the art [J]. Water, Air, & Soil Pollution, 1986, 30 (1): 75–90.

    [68] Balestrini R, Galli L, Tartari G. Wet and dry atmospheric deposition at prealpine and alpine sites in northern Italy [J]. Atmospheric Environment, 2000, 34 (9): 1455–1470.

    [69] Guo D H, Zhang T Y. 大气干沉降对降水缓冲作用的研究 [J]. Journal of Hubei University (Natural Science), 1987, 1: 100–104 (in Chinese).

    [70] Kimura S D, Saito M, Hara H, et al. Comparison of nitrogen dry deposition on cedar and oak leaves in the Tama Hills using foliar rinsing method [J]. Water, Air, &Soil Pollution, 2009, 202 (1): 369–377.

    [71] Weathers K C, Cadenasso M L, Sta P. Forest edges as nutrient and pollutant concentrators: potential synergisms between fragmentation, forest canopies, and the atomosphere [J]. Conservation Biology, 2002, 15 (6): 1506–1514.

    [72] Schaefer D A, Reiners W A. Throughfall Chemistry and Canopy Processing Mechanisms [M]. Acidic Precipitation. Springer New York, 1990: 241–284.

    [73] Draaijers G P J, Erisman J W. Atmospheric sulphur deposition to forest stands: Throughfall estimates compared to estimates from inference [J]. Atmospheric Environment. part A. general Topics, 1993, 27 (1): 43–55.

    [74] Schmitt M, Thöni L, Waldner P, et al. Total deposition of nitrogen on Swiss long-term forest ecosystem research (LWF) plots: comparison of the throughfall and the inferential method [J]. Atmospheric Environment, 2005, 39 (39): 1079–1091.

    [75] Tang Y S, Simmons I, Dijk N V, et al. European scale application of atmospheric reactive nitrogen measurements in a low-cost approach to infer dry deposition fluxes [J]. Agriculture Ecosystems&Environment, 2009, 133 (3): 183–195.

    [76] Vitale M, Gerosa G, Ballarin-Denti A, et al. Ozone uptake by an evergreen mediterranean forest (Quercus ilex, L. ) in Italy-Part II: flux modelling. Upscaling leaf to canopy ozone uptake by a process-based model [J]. Atmospheric Environment, 2005, 39 (18) 3267–3278.

    [77] Turnipseed A A, Huey L G, Nemitz E, et al. Eddy covariance fluxes of peroxyacetyl nitrates (PANs) and NO y, to a coniferous forest [J]. Journal of Geophysical Research Atmospheres, 2006, 111 (D9): 1485–1493.

    [78] Businger J A, Oncley S P. Flux Measurement with Conditional Sampling [J]. Journal of Atmospheric&Oceanic Technology, 2009, 7 (7): 349–352.

    [79] Cobos D R, Baker J M, Nater E A. Conditional Sampling for Measuring Mercury Vapor Fluxes[C] //AGU Fall Meeting. AGUFall Meeting Abstracts, 2001: 4309–4321.

    [80] Baldocchi D D, Hincks B B, Meyers T P. Measuring BiosphereAtmosphere Exchanges of Biologically Related Gases with Micrometeorological Methods [J]. Ecology, 1988, 69 (5): 1331–1340.

    [81] Horvath L, Weidinger T N Z. Estimation of dry deposition velocities of nitric oxide, sulfur dioxide, and ozone by the gradient method above short vegetation during the tract campaign [J]. Atmospheric Environment, 1998, 32 (7): 1317–1322.

    [82] Pan X L, Wang Z F, Wang X Q et al. An Observation Study of Ozone Dry Deposition over Grassland in the Suburban Area of Beijing [J]. Chinese Journal of Atmospheric Sciences, 2010, 34 (1): 120–130 (in Chinese).

    [83] Matsuda K, Watanabe I, Wingpud V, et al. Ozone dry deposition above a tropical forest in the dry season in northern Thailand [J]. Atmospheric Environment, 2005, 39 (14): 2571–2577.

    [84] Phillips S B, Arya S P, Aneja V P. Ammonia flux and dry deposition velocity from near-surface concentration gradient measurements over a grass surface in North Carolina [J]. Atmospheric Environment, 2004, 38 (21): 3469–3480.

    [85] Wang T J, Liu Q, Zhao H et al. Atomospheric nitrogen deposition in agrecosystem in red soil region of Jiangxi Province [J]. Acta Pedologica Sinica, 2008, 45 (2): 280–287 (in Chinese).

    [86] Shen J L, Liu X J, Zhang F S. Atmospheric dry depositions of ammonia and nitrogen dioxide to agricultural fields in perisuburbs of Beijing [J]. Acta Pedologica Sinica, 2008, 45 (1): 165–169 (in Chinese).

    [87] Deng J J, Wang T J, Li S et al. Study on atmospheric nitrogen oxidant and deposition flux in suburban of Nanjing [J]. Scientia Meteorologica Sinica, 2009, 29 (1): 25–30 (in Chinese).

    [88] Shen J L, Tang A H, Liu X J, et al. High concentrations and dry deposition of reactive nitrogen species at two sites in the North China Plain [J]. Environmental Pollution, 2009, 157 (11): 3106–3113.

    [89] Luo X S, Shi W Q, Lu L et al. Nitrogen deposition in typical cropland in the Leizhou Peninsula, China [J]. Acta Ecologica Sinica, 2014, 34 (19): 5541–5548 (in Chinese).

    [90] Yan W J, Shi K, Liu X J et al. Atmospheric deposition of reactive nitrogen in agricultural zone, Lushunkou, Dalian [J]. Environmental Chemistry, 2014, 33 (7): 1180–1186 (in Chinese).

    [91] Zhang J, Kang R H, Zhao B et al. Monitoring Nitrogen Deposition on Temperate Grassland in Inner Mongolia [J]. Environmental Science, 2013, 34 (9): 3552–3556 (in Chinese).

    [92] Wesely M L, Hicks B B. A review of the current status of knowledge on dry deposition [J]. Atmospheric Environment, 2000, 34 (12–14): 2261–2282.

    [93] Holland E A, Braswell B H, Sulzman J, et al. Nitrogen Deposition on the United States and Western Europe: Synthesis of Observations and Models [J]. Ecological Applications, 2008, 15 (1): 38–57.

    [94] Flechard C R, Nemitz E, Smith R I, et al. Dry deposition of reactive nitrogen to European ecosystems: a comparison of inferential models across the Nitro Europe network [J]. Atmospheric Chemistry & Physics, 2011, 2011 (6): 2703–2728.

    [95] Adon M, Galylacaux C, Yoboue V, et al. Dry deposition of nitrogen compounds (NO2, HNO3, NH3), sulfur dioxide and ozone in West and Central African ecosystems using the inferential method [J]. Atmospheric Chemistry & Physics, 2013, 13 (22): 11351–11374.

    [96] Clarke J F, Edgerton E S, Martin B E. Dry deposition calculations for the clean air status and trends network [J]. Atmospheric Environment, 1997, 31 (21): 3667–3678.

    [97] Zhang L, Brook J R, Vet R, et al. Estimation of contributions of NO2, and PAN to total atmospheric deposition of oxidized nitrogen across Eastern Canada [J]. Atmospheric Environment, 2005, 39 (37): 7030–7043.

    [98] Zhang M, Wang T J, Zhang Y et al. Observational study on atmospheric sulfur deposition to farmland ecosystem [J]. Journal of the Meteorological Sciences, 2003, 23 (3): 263–272 (in Chinese).

    [99] Fan J L, Hu Z Y, Zhuang S Y et al. Observation of atmospheric nitrogen deposition into forestland [J]. China Environmental Science, 2007, 27 (1): 7–9.

    [100] Miaomiao Cheng, Hong Jiang, Zheng Guo, et al. Estimating NO2 dry deposition using satellite data in eastern China [J]. International Journal of Remote Sensing, 2013, 34 (7): 2548–2565.

    [101] Nowlan C R, Martin R V, Philip S, et al. Global dry deposition of nitrogen dioxide and sulfur dioxide inferred from space-based measurements [J]. Global Biogeochemical Cycles, 2014, 28 (10): 1025–1043.

    [102] Xiao H Y, Liu C Q. Nitrogen isotope as a tracer in atmospheric environment and bio-indicators [J]. Earth Science Frontiers, 2010, 17 (2): 417–424 (in Chinese).

    [103] Hicks W K, Leith I D, Woodin S J, et al. Can the foliar nitrogen concentration of upland vegetation be used for predicting atmospheric nitrogen deposition? Evidence from field surveys [J]. Environmental Pollution, 2000, 107 (3): 367–76.

    [104] Skinner R A, Ineson P, Jones H, et al. Heathland vegetation as a bio-monitor for nitrogen deposition and source attribution using N values [J]. Atmospheric Environment, 2006, 40 (3): 498–507.

    [105] He C E, Liu X, Fangmeier A, et al. Quantifying the total airborne nitrogen input into agroecosystems in the North China Plain [J]. Agriculture Ecosystems & Environment, 2007, 121 (4): 395–400.

    [106] Xiao H Y, Liu X Y, Liu C Q. Tissue N Contents and Isotopic Ratios in Epilithic Mosses Indicating N Deposition and Transport in the Atmosphere [J]. Bulletin of Mineralogy, Petrology and Geochemistry, 2011, 30 (1): 18–25 (in Chinese).

    [107] Liu X Y, Xiao H Y, Liu C Q et al. Quantification of atmospheric nitrogen deposition at Guiyang area based on nitrogen concentration of epilithic mosses [J]. Acta Ecologica Sinica, 2009, 29 (12): 6646–6653 (in Chinese).

    [108] Xie Z Y, Xiao H Y, Zhu R G et al. Nitrogen Concentrations and Stable Isotope in Epilithic Mosses to Investigate Atmospheric N Deposition and N Sources in Jiangxi Province [J]. Environmental Science, 2011, 32 (4): 943–948 (in Chinese).

    [109] Xie Z Y, Xiao H Y, Luo L et al. Nitrogen concentrations and stable isotope in mosses to investigate atmospheric nitrogen deposition in rural areas [J]. China Environmental Science, 2011, 31 (7): 1128–1133 (in Chinese).

    [110] Luo L, Xiao H Y. Indication of Atmospheric Nitrogen Deposition in Mt. Lushan by Nitrogen Concentration and Nitrogen Isotope in Mosses [J]. Research of Environmental Sciences, 2011, 24 (5): 512–515 (in Chinese).

    [111] Weigel A, Russow R, Körschens M. Quantification of airborne N-input in long-term field experiments and its validation through measurements using 15N isotope dilution [J]. Journal of Plant Nutrition and Soil Science=Zeitschrift fuer Pflanzenernaehrung und Bodenkunde, 2000, 163 (3): 261–265.

    [112] Liu X Y, Xiao H Y, Liu C Q et al. δ 13C and δ 15N of moss (Haplocladium microphyllum (Hedw. ) Broth) for indicating habitats difference and canopy retention on atmospheric nitrogen deposition [J]. Geochimica, 2007, 36 (3): 286-294 (in Chinese).

    [113] Liu X Y, Xiao H Y, Liu C Q. A Discussion on the Deposition of Atmosphereic Nitrogen Indicated by the Nitrogen Isotopic Compositions (δ15N) of the Plant Leafage [J]. Bulletin of Mineralogy,Petrology and Geochemistry, 2007, 26 (4): 405–409 (in Chinese).

    [114] Xiao H Y, Liu C Q. Sources of nitrogen and sulfur in wet deposition at Guiyang, southwest China [J]. Atmospheric Environment, 2002, 36 (33): 5121–5130.

    [115] Jenkinson D S, Poulton P R, Johnston A E, et al. Turnover of Nitrogen-15-Labeled Fertilizer in Old Grassland [J]. Soil Science Society of America Journal, 2004, 68 (3): 865–875.

    [116] Fang Y, Gundersen P, Mo J, et al. Nitrogen leaching in response to increased nitrogen inputs in subtropical monsoon forests in southern China [J]. Forest Ecology & Management, 2009, 257 (1): 332–342.

    [117] Wang X, Wu Z, Shao M, et al. Atmospheric nitrogen deposition to forest and estuary environments in the Pearl River Delta region, southern China [J]. Tellus Series B-chemical & Physical Meteorology, 2013, 65 (1): 134–138.

    [118] Li J, Fang Y, Yoh M, et al. Organic nitrogen deposition in precipitation in metropolitan Guangzhou city of southern China [J]. Atmospheric Research, 2012, 113 (5): 57–67.

    [119] Chen Z Y, Li K M, Lin W S et al. Atmospheric dry and wet deposition of nitrogen and phosphorus in the Pearl River Estuary [J]. Environmental Pollution & Control, 2010, 32 (11): 53–57 (in Chinese).

    [120] Lu X, Mao Q, Gilliam F S, et al. Nitrogen deposition contributes to soil acidification in tropical ecosystems [J]. Global Change Biology, 2014, 20 (12): 3790–3801.

    [121] Fang Y T, Gundersen P, Mo J M, et al. Input and output of dissolved organic and inorganic nitrogen in subtropical forests of South China under high air pollution [J]. Biogeosciences, 2008, 5 (2): 339–352.

    [122] Wang Q, Wang X M, Lin W S et al. Study on Sources of Inorganic Nitrogen in Wet Deposition in Dinghushan Mountain [J]. Research of Environmental Sciences, 2008, 21 (6): 156–160 (in Chinese).

    [123] Fang Y T, Yoh M, Mo J M, et al. Response of nitrogen leaching to nitrogen deposition in disturbed and mature forests of southern China [J]. PEDOSPHERE, 2009, 19 (1): 111–120.

    [124] Fang Y, Wang X, Zhu F, et al. Three-decade changes in chemical composition of precipitation in Guangzhou city, southern China: has precipitation recovered from acidification following sulphur dioxide emission control? [J]. Tellus Series B-chemical & Physical Meteorology, 2013, 65 (9): 134–138.

    [125] Jia G, Chen F. Monthly variations in nitrogen isotopes of ammonium and nitrate in wet deposition at Guangzhou, south China [J]. Atmospheric Environment, 2010, 44 (19): 2309–2315.

    [126] Cao Y Z, Wang S Y, Zhang G, et al. Chemical characteristics of wet precipitation at an urban site of Guangzhou, South China [J]. Atmospheric Research, 2009, 94 (3): 462–469.

    [127] Wang Q, Wang X M, Zhong L J et al. Wet deposition of inorganic nitrogen and atmospheric transport at the estuary of the Pearl River [J]. Acta Scientiae Circumstantiae, 2009, 29 (6): 1156–1163 (in Chinese).

    [128] Fang Y T, Koba K, Wang X M, et al. Anthropogenic imprints on nitrogen and oxygen isotopic composition of precipitation nitrate in a nitrogen-polluted city in southern China [J]. Atmospheric Chemistry & Physics Discussions, 2011, 10 (9): 1313–1325.

    [129] Chen X Y, Mulder J. Atmospheric deposition of nitrogen at five subtropical forested sites in South China [J]. Science of the Total Environment, 2007, 378 (3): 317–330.

    [130] Aas W, Shao M, Jin L, et al. Air concentrations and wet deposition of major inorganic ions at five non-urban sites in China, 2001–2003 [J]. Atmospheric Environment, 2007, 41 (8): 1706–1716.

    [131] Huang X F, Xiang L, He L Y, et al. 5-Year study of rainwater chemistry in a coastal mega-city in South China [J]. Atmospheric Research, 2010, 97 (1): 185–193.

    [132] Huang Y, Lu X, Chen K. Wet atmospheric deposition of nitrogen: 20 years measurement in Shenzhen City, China [J]. Environmental Monitoring & Assessment, 2012, 185 (1): 113.

    [133] Wang Q, Wang X M, Zhong L J et al. Wet deposition of inorganic nitrogen and atmospheric transport at the estuary of the Pearl River [J]. Acta Scientiae Circumstantiae, 2009, 29 (6): 1156–1163 (in Chinese).

    [134] Xu Y G, Zhou G Y, Wu Z M, et al. Chemical Composition of Precipitation, Throughfall and Soil Solutions at Two Forested Sites in Guangzhou, South China [J]. Water, Air, & Soil Pollution, 2001, 130 (1): 1079–1084.

    [135] Yu D X, Ma X X, Tan B Q et al. Trend in Acid Deposition at Tieshanping, Chonging During 2001–2010 [J]. Environmental Science, 2014, 35 (1): 60–65 (in Chinese).

This Article



Vol 37, No. 12, Pages 4401-4416

December 2017


Article Outline


  • 1 Observation methods
  • 2 Application status
  • 3 Conclusions
  • References