植物源挥发性有机物对O3响应研究展望

Journal: Ecological Environment and Protection DOI: 10.12238/eep.v5i3.1593

张坤, 孙颖轩, 吴君龙, 郭美光子, 于妍

中国矿业大学(北京)化学与环境工程学院

Abstract

植物源挥发性有机化合物(BVOCs)作为地表臭氧(O3)的重要前体物,其排放对区域空气质量和气候变化有重要影响。O3是一种典型的植物毒素可影响植物正常的生理生长过程,同时影响植物BVOCs的排放。虽然近地层中O3的臭氧浓度不断上升,对生态系统的碳氮循环造成极大的影响,对生态环境的健康与安全构成了威胁。但是,O3对BVOCs的作用的研究却很少。本文总结了影响BVOCs的各种因素,另外还对O3对BVOCs的影响进行了讨论,并提出了在国内开展O3对BVOCs的影响研究的必要性和紧迫性。

Keywords

BVOCs;O3;全球变化

References

[1] 盛重义.有关大气污染控制工程教学问题的探讨[J].广东化工,2017,44(20):173-174.
[2] Guenther A,Hewitt C N, Erickson D,et al. A global model of natural volatile organic compound emissions[J].Journal of Geophysical Research: Atmospheres,1995,100(D5):8873-8892.
[3] 郑启伟,王效科,冯兆忠,等.用旋转布气法开顶式气室研究臭氧对水稻生物量和产量的影响[J].环境科学,2007,1(1):170
[4] 黄爽,赵天宏,金东艳,等.城市蒙古栎对近地层臭氧浓度升高的光合生理响应[J].辽宁林业科技,2009,(5):1-4.
[5] Penuelas J,Staudt M.BVOCs and global change[J].Trends Plant Science,2010,15(3):133-144.
[6] Yuan X Y,Feng Z Z,Liu S,et al.Concentration- and fluxbased dose-responses of isoprene emission from poplar leaves and plants exposed to an ozone concentration gradient[J]. Plant Cell & Environment,2017,40(9):1960-1971.
[7] Bonn B, von Schneidemesser E, Butler T, et al. Impact of vegetative emissions on urban ozone and biogenic seconda ry organic aerosol:Box model study for Berlin, Germany[J].Jou rnal of Cleaner Production,2018,176:827-841.
[8] Yao L,Ge M F,Qiao Z M,Sun Z,Wang D X. Progresses of trop ospheric chemistry of volatile organic compounds.Chemistry, 2006,69(5):049.
[9] Yan X F.Ecology of plant secondary metabolism.Acta Phytoecologica Sinica,2001,25(5):639-640.
[10] Kesselmeier J,Ciccioli P,Kuhn U,Stefani P,Biesenthal T,Rottenberger S,Wolf A,Vitullo M,Valentini R,Nobre A,Kabat P,Andreae M O.Volatile organic compound emissions in relation to plant carbon fixation and the terrestrial carbon budget. Global Biogeochemical Cycles,2002,16(4):1-9.
[11] Chen J, Tang J,Yu X. Environmental and physiological controls on diurnal and seasonal patterns of biogenic volatile organic compound emissions from five dominant woody species under field conditions[J].Environmental Pollution,2020,259:113955.
[12] Feng,Zhaozhong,Uddling J,Tang H ,et al. Comparison of crop yield sensitivity to ozone between open-top chamber and free-air experiments[J].Global Change Biology,2018,24(6):123-130.
[13] Xu S,Chen W, Huang Y Q, et al. Responses of Growth, Photosynthesis and VOC Emissions of Pinus tabulaeformis,Carr. Exposure to Elevated CO2,and/or Elevated O3,in an Urban Area [J].Bulletin of Environmental Contamination and Toxicology, 2012,88(3):443-448.
[14] Yuan X Y,Calatayud V,Feng G,et al. Interaction of drou ght and ozone exposure on isoprene emission from extensively cultivated poplar[J].Plant Cell &Environment,2016,39(10):2276 -2287.
[15] Biswas DK,Jiang GM.Differential drought-induced mo dulation of ozone tolerance in winter wheat species[J].Jour nal of Experimental Botany,2011,62(12):4153-4162.
[16] 冯兆忠,袁相洋,李品,等.地表臭氧浓度升高对陆地生态系统影响的研究进展[J].植物生态学报,2020,44(05):526-542.
[17] 袁相洋.复合环境因子对杨树异戊二烯释放的影响研究[D].北京:中国科学院大学,2017.
[18] Lucas P W,Cottam D A and Mansfield T A.Alarge-scale fumigation system for investigating interactions between air pollution and cold stress on plants[J].Environmental Pollution,1987,43(1):15-28.
[19] Heagle A S,Body D E,Heck W W.An Open-Top Field Cham ber to Assess the Impact of Air Pollution on Plants1[J].Journ al of Environmental Quality,1973,2(3):365-368.
[20] Uprety D.C,GARG,et al.Carbon dioxide enrichment tech nologies for crop response studies[J].Journal of Scientific Industrial Research,2006,65(11):859-866.
[21] 王明娜,孙彦坤,罗卫红,等.FACE条件下小麦冠层能量平衡和水分利用率的变化[J].中国生态农业学报,2009,17(2):266-272.

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