植物吸附大气颗粒物的影响因素和响应机制的研究进展。

Q3 Environmental Science 应用生态学报 Pub Date : 2024-07-18 DOI:10.13287/j.1001-9332.202407.028
Yun A, Jin-Qing Zhang, Hai-Juan Zhang, Rui-Zhen Dong
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引用次数: 0

摘要

植物可以有效地吸附和清除空气中的颗粒物,但同时也会受到不利影响。因此,探索植物与大气颗粒物之间的相互作用,对于深刻理解生态平衡、微环境气候和环境质量改善至关重要。很少有系统的文献阐述植物对大气颗粒物的吸附和响应机制。我们总结了大气颗粒物的成因和组成,以及植物对大气颗粒物的吸附方法和因素。此外,我们还阐述了大气颗粒物胁迫对表型和生理特征的影响以及分子机制。对于未来的研究,我们建议:1)选择适应性强、滞尘能力强的植物品种。随后,应根据植物群落结构、街道形态、种植空间等综合因素,制定出通用的绿色滞尘方案;2)将研究范围从城市扩展到农牧区,系统分析不同植物配置群落的综合滞尘能力;3)将植物滞尘能力与植物自身抗性有效结合。其次,探索植物响应大气颗粒物胁迫的生理和分子机制,建立综合评价体系和标准;4)开发原位标记检测技术,这将是在细胞水平准确追踪和量化植物体内大气颗粒物动态的重要工具。
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Research progress on the influencing factors and response mechanisms of plant adsorption of atmospheric particulate matter.

Plants could effectively adsorb and remove particulate matter from the air, while could be suffered from the adverse effects. Therefore, exploring the interaction between plants and atmospheric particulate matter is crucial for profound understanding of ecological balance, microenvironmental climate, and environmental quality improvement. Few systematic literature have elaborated the adsorption and response mechanisms of atmospheric particulate matter by plants. We summarized the causes and composition of atmospheric particulate matter, as well as the adsorption methods and factors of plants on atmospheric particulate matter. Moreover, we elaborated the impact of atmospheric particulate matter stress on phenotypic and physiological characteristics, as well as molecular mechanisms. For the future researches, we proposed 1) to select plant species with strong adaptability and high dust retention capacity. Subsequently, there should be a universal green dust retention plan on account of comprehensive factors such as plant community structure, street morphology, and planting space; 2) to extend the research from urban areas to agricultural and pastoral areas, with a systematic analysis of the comprehensive dust retention capacity of communities with different plant configuration; 3) to effectively combine the dust retention capacity of plants with their own resistance. Subsequently, we should explore the physiological and molecular mechanisms of plants responding to atmospheric particulate matter stress and establish a comprehensive evaluation system and criteria; 4) to develop in situ labeling detection technology, which would be a valuable tool for accurately tracing and quanti-fying the dynamics of atmospheric particulate matter within plant at the cellular level.

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来源期刊
应用生态学报
应用生态学报 Environmental Science-Ecology
CiteScore
2.50
自引率
0.00%
发文量
11393
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