地-气系统活性氮来源与转化的同位素示踪研究进展

doi:10.13287/j.1001-9332.202409.031

摘要/Abstract

摘要： 工业革命以来,人为活动导致活性氮的产生快速持续增加,造成了地表氮富集,诱发了一系列生态环境问题。稳定同位素是示踪物质来源和环境过程机制的有效手段之一。地表环境中活性氮化合物的氮同位素值整合了不同来源氮的同位素值和转化过程中的同位素分馏效应。因此,氮同位素组成可用于示踪地表氮素来源和循环过程,进而服务于地表活性氮减排策略的制定和地表氮富集的生态环境效应的评估。本文总结了氮同位素在大气系统活性氮来源、植物氮利用以及森林生态系统氮过程示踪中的研究进展,并对如何更加系统和准确地理解地表各圈层内以及圈层间的氮循环进行了展望。

关键词: 大气氮沉降, 氮同位素, 同位素效应, 氮循环, 氮输出

Abstract: Since the Industrial Revolution, human activities have led to a rapid and sustained increase in reactive nitrogen production, resulting in nitrogen enrichment at the Earth's surface and triggering many ecological and environmental issues. Stable isotopes are effective tools for tracing the sources and mechanisms of environmental processes. The nitrogen isotope values in surface environments integrate the isotope signatures of different nitrogen sources and the isotope fractionation effects of transformation processes. The composition of nitrogen isotopes can thus be utilized to trace the sources and cycling of nitrogen at the surface, aiding the development of strategies to reduce reactive nitrogen emissions, and assess the ecological effects of nitrogen enrichment. We reviewed the research progress on nitrogen isotope in the sources of reactive nitrogen in atmospheric systems, plant nitrogen utilization, and tracking of nitrogen processes in forest ecosystems. We further discussed how to gain a more systematic and accurate understanding of nitrogen cycle within and between the various spheres of the surface environment.

Key words: atmospheric nitrogen deposition, nitrogen isotope, isotope effect, nitrogen cycle, nitrogen output

宋韦, 刘学炎. 地-气系统活性氮来源与转化的同位素示踪研究进展[J]. 应用生态学报, 2024, 35(9): 2362-2371.

SONG Wei, LIU Xueyan. Research progress on isotope tracing on the sources and transformations of reactive nitrogen in the earth-atmosphere system[J]. Chinese Journal of Applied Ecology, 2024, 35(9): 2362-2371.

参考文献

[1] Chapin FS, Matson PA, Mooney HA, et al. Principles of Terrestrial Ecosystem Ecology. New York: Springer, 2011
[2] Vitousek PM, Howarth RW. Nitrogen limitation on land and in the sea: How can it occur? Biogeochemistry, 1991, 13: 87-115
[3] Stevens CJ. Nitrogen in the environment. Science, 2019, 363: 578-580
[4] Richardson K, Steffen W, Lucht W, et al. Earth beyond six of nine planetary boundaries. Science Advances, 2023, 9: eadh2458
[5] Xiao HY, Liu CQ. Sources of nitrogen and sulfur in wet deposition at Guiyang, southwest China. Atmospheric Environment, 2002, 36: 5121-5130
[6] 程谊, 蔡祖聪, 张金波. ¹⁵N同位素稀释法测定土壤氮素总转化速率研究进展. 土壤, 2009, 41(2): 165-171
[7] 史贵涛, 秦瑞, 马红梅, 等. 南极雪冰中硝酸根稳定同位素研究进展. 极地研究, 2019, 31(2): 117-127
[8] 项妍琨, 曹芳, 杨笑影, 等. 利用次溴酸盐氧化结合盐酸羟胺还原法测定大气气溶胶样品铵态氮同位素. 应用生态学报, 2019, 30(6): 1847-1853
[9] 董鑫媛, 郭庆军, 魏荣菲, 等. 大气硝酸盐氧同位素异常及应用进展. 生态学杂志, 2020, 39(3): 1022-1032
[10] 李靳, 康荣华, 于浩明, 等. 土壤水分对土壤产生气态氮的厌氧微生物过程的影响. 应用生态学报, 2021, 32(6): 1989-1997
[11] 刘文景, 孙会国, 李源川, 等. 怒江水化学与碳同位素组成对青藏高原岩石风化碳汇效应的指示. 中国科学: 地球科学, 2023, 53(12): 2992-3009
[12] Robinson D. δ¹⁵N as an integrator of the nitrogen cycle. Trends in Ecology and Evolution, 2001, 16: 153-162
[13] Wang YL, Song W, Yang W, et al. Influences of atmospheric pollution on the contributions of major oxidation pathways to PM_2.5 nitrate formation in Beijing. Journal of Geophysical Research-Atmospheres, 2019, 124: 4174-4185
[14] Song W, Liu XY, Liu CQ. New constraints on isotopic effects and major sources of nitrate in atmospheric particulates by combining δ¹⁵N and Δ¹⁷O signatures. Journal of Geophysical Research: Atmospheres, 2021, 126: e2020JD034168
[15] Zhang YL, Zhang W, Fan MY, et al. A diurnal story of Δ¹⁷O (NO₃^-) in urban Nanjing and its implication for nitrate aerosol formation. NPJ Climate and Atmospheric Science, 2022, 5: 50
[16] Zhang ZY, Jiang Z, Zhou T, et al. Reconciling modeled and observed Δ¹⁷O (NO₃^-) in Beijing winter haze with heterogeneous chlorine chemistry. Journal of Geophysical Research: Atmospheres, 2024, 129: e2023JD039740
[17] Song W, Liu XY, Wang YL, et al. Nitrogen isotope differences between atmospheric nitrate and corresponding nitrogen oxides: A new constraint using oxygen isotopes. Science of the Total Environment, 2020, 701: 134515
[18] Fan MY, Zhang WQ, Zhang YL, et al. Formation mechanisms and source apportionments of nitrate aerosols in a megacity of eastern China based on multiple isotope observations. Journal of Geophysical Research: Atmospheres, 2023, 128: e2022JD038129
[19] Song W, Liu XY, Hu CC, et al. Important contributions of non-fossil fuel nitrogen oxides emissions. Nature Communications, 2021, 12: 243
[20] Zong Z, Wang XP, Tian CG, et al. First assessment of NO_x sources at a regional background site in North China using isotopic analysis linked with modeling. Environmental Science & Technology, 2017, 51: 5923-5931
[21] Luo L, Wu YF, Xiao HY, et al. Origins of aerosol nitrate in Beijing during late winter through spring. Science of the Total Environment, 2019, 653: 776-782
[22] Zong Z, Tian CG, Sun ZY, et al. Long-Term evolution of particulate nitrate pollution in North China: Isotopic evidence from 10 offshore cruises in the Bohai Sea from 2014 to 2019. Journal of Geophysical Research: Atmospheres, 2022, 127: e2022JD036567
[23] Zhang EZ, Li J, Zhang RJ, et al. Increase in agricultural-derived NH_x and decrease in coal combustion-derived NO_x result in atmospheric particulate N-NH₄⁺ surpassing N-NO₃^- in the South China Sea. Environmental Science & Technology, 2024, 58: 6682-6692
[24] Song W, Liu XY, Houlton BZ, et al. Isotopic constraints confirm the significant role of microbial nitrogen oxides emissions from the land and ocean environment. National Science Review, 2022, 9: nwac106
[25] Ciais PC, Sabine G, Bala L, et al. Carbon and other biogeochemical cycles// IPCC, ed. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press, 2013
[26] Zheng XD, Liu XY, Song W, et al. Nitrogen isotope variations of ammonium across rain events: Implications for different scavenging between ammonia and particulate ammonium. Environmental Pollution, 2018, 239: 392-398
[27] Jia GD, Chen FJ. Monthly variations in nitrogen isotopes of ammonium and nitrate in wet deposition at Guangzhou, south China. Atmospheric Environment, 2010, 44: 2309-2315
[28] Chang YH, Liu XJ, Deng CR, et al. Source apportionment of atmospheric ammonia before, during, and after the 2014 APEC summit in Beijing using stable nitrogen isotope signatures. Atmospheric Chemistry and Physics, 2016, 16: 11635-11647
[29] Pan YP, Tian SL, Liu DW, et al. Fossil fuel combustion-related emissions dominate atmospheric ammonia sources during severe haze episodes: Evidence from ¹⁵N-stable isotope in size-resolved aerosol ammonium. Environmental Science & Technology, 2016, 50: 8049-8056
[30] Xiao HW, Wu JF, Luo L, et al. Enhanced biomass burning as a source of aerosol ammonium over cities in central China in autumn. Environmental Pollution, 2020, 266: 115278
[31] Zhang YY, Benedict KB, Tang AH, et al. Persistent nonagricultural and periodic agricultural emissions dominate sources of ammonia in urban Beijing: Evidence from ¹⁵N stable isotope in vertical profiles. Environmental Science & Technology, 2020, 54: 102-109
[32] Heaton THE, Spiro B, Robertson SMC. Potential canopy influences on the isotopic composition of nitrogen and sulphur in atmospheric deposition. Oecologia, 1997, 109: 600-607
[33] Xiao HW, Xiao HY, Long A, et al. Who controls the monthly variations of NH₄⁺ nitrogen isotope composition in precipitation? Atmospheric Environment, 2012, 54: 201-206
[34] Ti CP, Gao B, Luo YX, et al. Isotopic characterization of NH_x-N in deposition and major emission sources. Biogeochemistry, 2018, 138: 85-102
[35] Chen ZL, Song W, Hu CC, et al. Significant contributions of combustion-related sources to ammonia emissions. Nature Communications, 2022, 13: 7710
[36] Liu XY, Koba K, Liu CQ, et al. Pitfalls and new mechanisms in moss isotope bio-monitoring of atmospheric nitrogen deposition. Environmental Science & Technology, 2012, 46: 12557-12566
[37] Liu XY, Wu D, Song X, et al. A non-steady state model based on dual nitrogen and oxygen isotopes to constrain moss nitrate uptake and reduction. Journal of Geophysical Research: Biogeosciences, 2020, 125: e2019JG005498
[38] Dong YP, Huang H, Song W, et al. Natural ¹³C and ¹⁵N abundance of moss-substrate systems on limestones and sandstones in a karst area of subtropical China. Catena, 2019, 180: 8-15
[39] Liu XY, Koba K, Koyama L, et al. Nitrate is an important nitrogen source for arctic tundra plants. Proceedings of the National Academy of Sciences of the United States of America, 2018, 115: 3398-3403
[40] Liu XY, Koba K, Makabe A, et al. Ammonium first: Natural mosses prefer atmospheric ammonium but vary utilization of dissolved organic nitrogen depending on habitat and nitrogen deposition. New Phytologist, 2013, 199: 407-419
[41] Hu CC, Lei YB, Tan YH, et al. Plant nitrogen and phosphorus utilization under invasive pressure in a montane ecosystem of tropical China. Journal of Ecology, 2019, 107: 372-386
[42] Liu XY, Koba K, Makabe A, et al. Nitrate dynamics in natural plants: Insights based on the concentration and natural isotope abundances of tissue nitrate. Frontiers in Plant Science, 2014, 5: 355
[43] Huang H, Song W, Liu XY. Significant contributions of combustion NH₃ and non-fossil fuel NO_x to increases of nitrogen deposition in southwestern China over past five decades. Global Change Biology, 2021, 27: 4392-4402
[44] Fenn ME, Ross CS, Schilling SL, et al. Atmospheric deposition of nitrogen and sulfur and preferential canopy consumption of nitrate in forests of the Pacific Northwest, USA. Forest Ecology and Management, 2013, 302: 240-253
[45] Van Langenhove L, Verryckt LT, Brechet L. Atmospheric deposition of elements and its relevance for nutrient budgets of tropical forests. Biogeochemistry, 2020, 149: 175-193
[46] Fang YT, Yoh M, Koba K, et al. Nitrogen deposition and forest nitrogen cycling along an urban-rural transect in southern China. Global Change Biology, 2011, 17: 872-885
[47] Guerrieri R, Templer P, Magnani F. Canopy exchange and modification of nitrogen fluxes in forest ecosystems. Current Forestry Reports, 2021, 7: 115-137
[48] Liu XY, Liu MN, Qin WX, et al. Isotope constraints on nitrate exchanges between precipitation and forest canopy. Global Biogeochemical Cycles, 2023, 37: e2023GB007920
[49] Zhang JB, Cai ZC, Zhu TB, et al. Mechanisms for the retention of inorganic N in acidic forest soils of southern China. Scientific Reports, 2013, 3: 2342
[50] Li Z, Tian D, Wang B, et al. Microbes drive global soil nitrogen mineralization and availability. Global Change Biology, 2019, 25: 1078-1088
[51] Elrys AS, Ali A, Zhang H, et al. Patterns and drivers of global gross nitrogen mineralization in soils. Global Change Biology, 2021, 27: 5950-5962
[52] Isobe K, Ise Y, Kato H, et al. Consequences of microbial diversity in forest nitrogen cycling: Diverse ammonifiers and specialized ammonia oxidizers. The ISME Journal, 2020, 14: 12-25
[53] Denk TRA, Kraus D, Kiese R, et al. Constraining N cycling in the ecosystem model Landscape DNDC with the stable isotope model SIMONE. Ecology, 2019, 100: e02675
[54] Houlton BZ, Sigman DM, Hedin LO. Isotopic evidence for large gaseous nitrogen losses from tropical rainforests. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103: 8745-8750
[55] Stark JM, Hart SC. High rates of nitrification and nitrate turnover in undisturbed coniferous forests. Nature, 1997, 385: 61-64
[56] Zhang JB, Zhu TB, Cai ZC, et al. Nitrogen cycling in forest soils across climate gradients in Eastern China. Plant and Soil, 2011, 342: 419-432
[57] Zak JC, Willig MR, Moorhead DL, et al. Functional diversity of microbial communities: A quantitative approach. Soil Biology and Biochemistry, 1994, 26: 1101-1108
[58] Kuypers MMM, Marchant HK, Kartal B. The microbial nitrogen-cycling network. Nature Reviews Microbiology, 2018, 16: 263-276
[59] Xu SQ, Liu XY, Sun ZC, et al. Isotopic elucidation of microbial nitrogen transformations in forest soils. Global Biogeochemical Cycles, 2021, 35: e2021GB007070
[60] Oura N, Shindo J, Fumoto T, et al. Effects of nitrogen deposition on nitrous oxide emissions from the forest floor. Water, Air, and Soil Pollution, 2001, 130: 673-678
[61] 贺纪正, 张丽梅. 土壤氮素转化的关键微生物过程及机制. 微生物学通报, 2013, 40(1): 98-108
[62] Yu HM, Duan YH, Mulder J, et al. Universal temperature sensitivity of denitrification nitrogen losses in forest soils. Nature Climate Change, 2023, 13: 726-734
[63] 郭浩然. 高氮沉降下森林溪流水碳氮浓度与同位素特征及其环境意义. 博士论文. 天津: 天津大学, 2022
[64] Huang SN, Wang F, Elliott EM, et al. Multiyear mea-surements on Δ¹⁷O of stream nitrate indicate high nitrate production in a temperate forest. Environmental Science & Technology, 2020, 54: 4231-4239
[65] Fang YT, Koba K, Makabe A, et al. Microbial denitrification dominates nitrate losses from forest ecosystems. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112: 1470-1474