Phytoremediating the air down under: Evaluating airborne particulate matter accumulation by 12 plant species in Australia

Ecological Research Pub Date : 2024-06-12 DOI:10.1111/1440-1703.12493

Anamika Roy, Mamun Mandal, A. Przybysz, Alison Haynes, Sharon A. Robinson, Abhijit Sarkar, R. Popek

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Abstract

Atmospheric particulate matter (PM) is the most inhaled hazardous air pollutant that can cause adverse health impacts. Plants can remove such contaminants and act as biological filters through phytoremediation. In this study, we screened 12 Australian native species (two deciduous trees, three evergreen shrubs, and seven evergreen trees) growing in three regions to determine their potential in accumulating leaf surface (SPM) and in‐wax PM (WPM). Among the screened species, Lagunaria patersonia (139.22 μg cm−2) was the most effective PM accumulator, followed by Ficus obliqua (131.02 μg cm−2). L. patersonia is an Australian native tree with a dense crown that can efficiently trap PM due to air turbulence between its leaves and branches; broad leaves with a rough texture enhance the plant's ability to trap PM. On the contrary, morphological characteristics like evergreen leaves with hairy appendages may act as an efficient trap for PM in F. obliqua. Due to smoother leaves, the least effective species were F. rubignosa and Eucalyptus saligna. In addition to leaf shape, leaf structures and micromorphology influence PM accumulation. For instance, Pittosporum undulatum accumulated more PM due to its wrinkled and folded leaf structures despite a significantly lower waxes layer. The findings highlight the importance of planting efficient PM accumulator species to shield vulnerable areas from pollution and decrease human exposure to pollutants. The sink capacity of these species can be used in urban tree planning to combat air pollution and improve air quality.

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对澳大利亚的空气进行植物修复：评估澳大利亚 12 种植物对空气中微粒物质的积累情况

大气颗粒物（PM）是吸入量最大的有害空气污染物，可对健康造成不利影响。植物可以清除这些污染物，并通过植物修复起到生物过滤器的作用。在这项研究中，我们筛选了生长在三个地区的 12 种澳大利亚本地物种（两种落叶乔木、三种常绿灌木和七种常绿乔木），以确定它们在积累叶面可吸入颗粒物（SPM）和蜡内可吸入颗粒物（WPM）方面的潜力。在筛选出的树种中，Lagunaria patersonia（139.22 微克/厘米-2）是最有效的可吸入颗粒物累积者，其次是 Ficus obliqua（131.02 微克/厘米-2）。L. patersonia 是一种澳大利亚本土树种，树冠茂密，叶片和树枝之间的空气湍流可有效捕集可吸入颗粒物；质地粗糙的宽大叶片增强了植物捕集可吸入颗粒物的能力。相反，常绿植物叶片的形态特征（如带毛的附属物）可能会成为 F. obliqua 有效捕集可吸入颗粒物的因素。由于叶片较光滑，效果最差的物种是 F. rubignosa 和 Eucalyptus saligna。除了叶形，叶片结构和微形态也会影响可吸入颗粒物的积累。例如，海桐（Pittosporum undulatum）尽管蜡质层明显较低，但其皱褶和折叠的叶片结构积累了更多的可吸入颗粒物。研究结果突出表明，种植高效的可吸入颗粒物积累物种对于保护脆弱地区免受污染和减少人类接触污染物的机会非常重要。这些树种的吸收能力可用于城市树木规划，以应对空气污染和改善空气质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Ecological Research

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