园林植物对大气细颗粒物浓度的正负作用评价

doi:10.11923/j.issn.2095-4050.cjas20190500050

农学学报 ›› 2019, Vol. 9 ›› Issue (11): 44-49.doi: 10.11923/j.issn.2095-4050.cjas20190500050

所属专题：农业气象

园林植物对大气细颗粒物浓度的正负作用评价

李新宇^1,2,3, 赵松婷^1,2,3, 许蕊^1,2,3, 李延明^1,2,3

1.<2.sub>3.北京市园林科学研究院

收稿日期:2019-05-20 修回日期:2019-07-25 接受日期:2019-08-23 出版日期:2019-11-19 发布日期:2019-11-19
通讯作者: 李延明 E-mail:32507872@qq.com
基金资助:
北京市科技计划重大课题“北方地区城市背景下多尺度绿化生态效益评价体系的研究及建立”(D171100007117001)

Positive and Negative Effects of Landscape Plants on Atmospheric Fine Particulate Matter Concentration

Received:2019-05-20 Revised:2019-07-25 Accepted:2019-08-23 Online:2019-11-19 Published:2019-11-19

摘要/Abstract

摘要： 针对于园林绿地对城市大气环境中发挥的双重作用，本研究综合评价不同植物种类对消减PM2.5污染的能力差异，以期为城市绿地功能优化与提升提供科学依据。以北京市常用园林绿化植物为试验材料，在目前构建的植物叶片滞留细颗粒物质量的计算模型的基础上，考虑植物释放VOCs对大气颗粒物浓度的贡献量作为一个影响因子参与计算，对植物个体消减细颗粒物的净效益进行研究。结果表明：（1）植物个体之间滞留PM2.5能力有很大的差异，单位叶面积PM2.5滞留量较多的植物有元宝枫、大叶黄杨、胡枝子、锦带花、樱花，较少的为黄栌、旱柳、油松、七叶树；（2）油松、黄栌、圆柏3种植物由于释放α-蒎烯的量较高，对生成SOA的贡献较高；（3）综合评价植物消减细颗粒物的净效益，黄栌与油松2种植物对PM2.5没有消减作用，反而增加空气PM2.5浓度，其余13种植物对PM2.5具有消减作用，其中锦带花与元宝枫2种植物单位叶面积对PM2.5的消减能力最强。

关键词: 文献计量学, 文献计量学, 关键词共现, 作者合著, 作者共被引, 机构合作, 知识图谱

Abstract: In view of the dual role of garden green space in urban atmospheric environment, this study comprehensively evaluated the differences of PM2.5 pollution reduction ability of different plant species in order to provide scientific basis for the optimization and upgrading of urban green space function. Based on the current model of calculating the quality of fine particulate matter retained in plant leaves, taking the contribution of VOCs released by plants to the concentration of atmospheric particulate matter as an influencing factor, the net benefit of reducing fine particulate matter by plants was studied. The results showed us that: (1) there were big differences among the plants individuals of the capability of fine particles retention by trees in every unit leaf area for 7 days. Deciduous tree of Acer truncatum (0.606 g/m2) was more than 14 times as Aesculus chinensis (0.044 g/m2). Evergreen tree of Sabina chinensis (0.173 g/m2) was more than 2 times as Pinus tabuliformis (0.077 g/m2). (2) Pinus tabulaeformis, Cotinus coggygria and Sabina chinensis have higher contribution to the generation of SOA due to their higher release of alpha-pinene. (3) Comprehensive evaluation of the net benefits of reducing fine particulate matter in plants, Cotinus coggygria and Pinus tabulaeformis did not reduce PM2.5, but increased the concentration of PM2.5 in air. The other 13 plants all had a reduction effect on PM2.5, including Weigela florida and Acer truncatum. Leaf area had the strongest ability to reduce PM2.5.

李新宇,赵松婷,许蕊,李延明. 园林植物对大气细颗粒物浓度的正负作用评价[J]. 农学学报, 2019, 9(11): 44-49.

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园林植物对大气细颗粒物浓度的正负作用评价

Positive and Negative Effects of Landscape Plants on Atmospheric Fine Particulate Matter Concentration

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