ZHAO Yunge,LU Xiaoying,LIU Bin,et al.Study on Four Kinds of Greening Tree Retention PM2.5 and Leaf Surface Morphology During Summer in Beijing, China[J].Research of Soil and Water Conservation,2016,23(06):52-58.
夏季绿化树种滞留PM2.5与叶片微形态特征研究
- Title:
- Study on Four Kinds of Greening Tree Retention PM2.5 and Leaf Surface Morphology During Summer in Beijing, China
- 关键词:
- PM2.5; 叶表面微形态; 原子力显微镜(AFM); 气溶胶再发生器; 绿化树种
- 分类号:
- X173
- 摘要:
- 研究于夏季在北京大兴选取6个绿化树种(油松、白皮松、柳树、五角枫、银杏、杨树)为对象,应用气溶胶再发生器对林木叶片PM2.5吸附量进行定量分析,并应用原子力显微镜(AFM)观察叶表面微形态特征,测定叶表面粗糙度等参数,阐释植物叶片吸附PM2.5机制。结果表明:单位叶面积PM2.5吸附量排序为:油松[(0.057±0.004)μg/cm2]>白皮松[(0.052±0.001)μg/cm2]>柳树[(0.041±0.003)μg/cm2]>五角枫[(0.036±0.007)μg/cm2]>杨树[(0.021±0.002)μg/cm2]>银杏[(0.018±0.003)μg/cm2];从月份变化来看,单位叶面积PM2.5吸附量表现为9月[(0.040±0.017)μg/cm2]> 7月[(0.039±0.015)μg/cm2]> 8月[(0.034±0.016)μg/cm2];针叶树种单位叶面积PM2.5吸附量高于阔叶树种。植物叶表面存在褶皱、沟槽,粗糙度相对较高的树种,吸附PM2.5能力较强;叶表面相对光滑,突起部位轮廓较平缓,粗糙度小的树种,其吸附PM2.5能力也相对较弱;6个树种粗糙度大小与其吸附PM2.5能力大小顺序完全一致,呈显著正相关(R2=0.957)。因此,为提高城市植被的环境效应,可选择叶表面形态有利于吸滞PM2.5等颗粒物的油松、白皮松等针叶树种。
- Abstract:
- Six kinds of greening tree species (Pinus tabulaeformis, Pinus bungeana, Salix babylonica, Acer mono Maxim, Ginkgo biloba, Populus L.) in Daxing District of Beijing were studied, aerosol generator was applied to quantitatively study leaves PM2.5 adsorption, and atomic force microscopy (AFM) was used to observe leaf surface morphology, and analyze the leaf surface roughness parameters, interpret the PM2.5 adsorbing mechanism of green plant. The results showed that the sequence of PM2.5 adsorption capacity per unit leaf area was Pinus tabulaeformis[(0.057±0.004)μg/cm2] > Pinus bungeana[(0.052±0.001)μg/cm2] > Salix babylonica[(0.041±0.003)μg/cm2] > Acer mono Maxim[(0.036±0.007)μg/cm2] > Populus L.[(0.021±0.002)μg/cm2] > Ginkgo biloba[(0.018±0.003)μg/cm2], and the sequence of PM2.5 adsorption capacity per unit leaf area in different months was September[(0.040±0.017)μg/cm2] > July[(0.039±0.015)μg/cm2] > August[(0.034±0.016)μg/cm2]; PM2.5 adsorption of coniferous species was higher than that of broad-leaf species. Fluted or grooved leaves had greater roughness than those with smooth leaf surface, and PM2.5 adsorption capacity enhanced with the increase of roughness of leaf surface. Tendency of PM2.5 adsorption capacity consistently changed with leaves roughness, and the leaves roughness was significantly related to PM2.5 adsorption capacity (R2=0.957). In order to improve the environmental effect of urban vegetation, the tree species whose leaf surface morphology is conducive to adsorb PM2.5 and other particles should be planted, such as Pinus tabulaeformis and Pinus bungeana.
参考文献/References:
[1] 李海梅,刘霞.青岛市城阳区主要园林树种叶片表皮形态与滞尘量的关系[J].生态学杂志,2008,27(10):1659-1662.
[2] Christoforou C S, Salmon L G, Hannigan M P, et al. Trends in fine particle concentration and chemical composition in Southern California[J]. Journal of the Air & Waste Management Association, 2000,50(1):43-53.
[3] David V B. Assessing the causality inference in the case of particulate pollution[J]. Environmental Health Perspectives, 2000,108(2):91-92.
[4] 关欣,李巧云,文倩,等.和田降尘与浮尘、扬尘、沙尘暴的关系研究[J].环境科学研究,2000,13(6):1-3.
[5] Plaza J, Gomez-Moreno F J, Nunez L, et al. Estimation of secondary organic aerosol formation from semi-continuous OC-EC measurements in a Madrid suburban area[J]. Atmospheric Environment, 2006,40(6):1134-1147.
[6] Hsu S C, Liu S C, Jeng W L, et al. Variations of Cd/Pb and Zn/Pb ratios in Taipei aerosols reflecting long-range transport or local pollution emissions[J]. Science of the Total Environment, 2005,347(1/3):111-121.
[7] Deng W J, Louie P K K, Liu W K, et al. Atmospheric levels and cytotoxicity of PAHs and heavy metals in TSP and PM2.5 at an electronic waste recycling site in southeast China[J]. Atmospheric Environment, 2006,40(36):6945-6955.
[8] 刘大锰,马永胜,高少鹏,等.北京市区春季燃烧源大气颗粒物的污染水平和影响因素[J].现代地质,2005,19(4):627-633.
[9] Beckett K P, Freer Smith P H, Taylor G. Effective tree species for local air quality management[J]. Journal of Arboriculture, 2000,26(1):12-19.
[10] Chen Z X, Su X H, Liu S Z. Study of ecological effect of urban green space in Beijing[J]. Chin Landscape Architech, 1998,14(2):51-54.
[11] Cowell F R. The garden as a fine art:From antiquity to modern times[M]. London:Weidenfeld and Nicolson, 1978.
[12] Hwang H J, Yook S J, Ahn K H. Experimental investigation of submicron and ultrafine soot particle removal by tree leaves[J]. Atmospheric Environment, 2011,45(38):6987-6994.
[13] McDonald A G, Bealey W J, Fowler D, et al. Quantifying the effect of urban tree planting on concentrations and depositions of PM10 in two UK conurbations[J]. Atmospheric Environment, 2007,41(38):8455-8467.
[14] McPherson E G, Nowak D J, Rowntree R A. Chicago’s urban forest ecosystem:Results of the Chicago Urban Forest Climate Project.(Includes executive summary). Forest Service general technical report (Final)[R]. Delaware, OH (United States):Forest Service-Northeastern Forest Experiment Station, 1994..
[15] Yin S, Shen Z, Zhou P, et al. Quantifying air pollution attenuation within urban parks:An experimental approach in Shanghai, China[J]. Environmental Pollution, 2011,159(8):2155-2163.
[16] 王兵,张维康,牛香,等.北京10个常绿树种颗粒物吸附能力研究[J].环境科学,2015,36(2):408-414.
[17] Davila A F, Rey D, Mahamed K, et al. Mapping the sources of urban dust in a coastal environment by measuring magnetic parameters of Platanus hispanica leaves[J]. Environmental & Technology, 2006,40(12):3922-3928.
[18] Cai Y L, Song Y C.2001. Adaptive ecology of lianas in tiantong evergreen broad-leaved forest, Zhejiang, China I. Leaf anatomical characters[J]. Acta Phytoecological Sinica.2001,25(1):90-98.
[19] Prusty B A K, Mishra P C, Azeez P A. Dust accumulation and leaf pigment content in vegetation near the national highway at Sambalpur, Orissa, India[J]. Ecotoxicity and Environmental Safety, 2005,60(2):228-235.
[20] Beckett K P, Freer-Smith P H, Taylor G. Urban woodlands:their role in reducing the effects of particulate pollution. Environmental Pollution, 1998,99(3):347-360.
[21] Sabin L D, Hee Lim J, Teresa Venezia M, et al. Dry deposition and resuspension of particle-associated metals near a freeway in Los Angeles[J]. Atmospheric Environment, 2006,40(39):7528-7538.
[22] Free-Smith P H, Sophy H, Goodman A. The uptake of particulates by an urban woodland:Site description and particulate composition[J]. Environmental Pollution, 1997,95(1):27-35.
[23] 石辉,王会霞,李秧秧,等.女贞和珊瑚树叶片表面特征的AFM观察[J].生态学报,2011,31(5):1471-1477.
[24] 贾彦,吴超,董春芳,等.7种绿化植物滞尘的微观测定[J].中南大学学报:自然科学版,2012,43(11):2362-2366.
[25] 王建辉,刘奕清,邹敏.永川城区主要绿化植物的滞尘效应[J].环境工程学报,2013,7(3):1079-1084.
[26] 刘璐,管东生,陈永勤.广州市常见行道树种叶片表面形态与滞尘能力[J].生态学报,2013,33(8):2604-2614.
[27] 王蕾,哈斯,刘连友,等.北京市六种针叶树叶面附着颗粒物的理化特征[J].应用生态学报,2007,18(3):487-492.
[28] 刘玲,方炎明,王顺昌,等.7种树木的叶片微形态与空气悬浮颗粒吸附及重金属累积特征[J].环境科学,2013,34(6):2361-2367.
[29] R?s?nen J V, Holopainen T, Joutsensaari J, et al. Effects of species-specific leaf characteristics and reduced water availability on fine particle capture efficiency of trees[J]. Environmental pollution, 2013,183:64-70.
[30] Smith W H. Pollutant uptake by plants[C]//Treshow M. Air Pollution and Plant Life. New York:John Wiley & Sons,1984.
[31] Davidson C I, Wu Y L. Dry deposition of particles and vapors[J]. Advances in Environmental Science, 1990,3(1):103-216.
[32] Gao J H, Wang D M, Zhao L, et al. Airborne dust detainment by different plant leaves:Taking Beijing as an example[J]. Journal of Beijing Forestry University, 2007,29(2):94-99.
[33] Nowak D J, Crane D E, Stevens J C. Air pollution removal by urban trees and shrubs in the United States[J]. Urban Forestry & Urban Greening, 2006,4(3):115-123.
备注/Memo
收稿日期:2016-04-19;改回日期:2016-05-03。
基金项目:国家林业局林业公益性行业科研专项(20130430101);北京市农林科学院科技创新能力建设专项“北京燕山森林生态国家站基础数据平台建设”;科技创新服务能力建设—协同创新中心—林果业生态环境功能提升协同创新中心(2011协同创新中心)(市级)(PXM2016_014207_000038)
作者简介:赵云阁(1990-)女,河北阳原人,在读硕士,主要研究方向:森林经理学。E-mail:675420514@qq.com
通讯作者:李少宁(1975-),男,河北滦县人,博士,副研究员,主要从事城市森林生态功能研究。E-mail:lishaoning@126.com