Potentially toxic elements capture by an active living wall in indoor environments: Effect of species in air phytoremediation

Indoor air pollution is a serious health problem throughout the world. Plants are known to be able to reduce the effect of air pollution and improve indoor air quality (IAQ). The aim of the present study was to compare the effectiveness of four plant species (Tradescantia zebrina hort. ex Bosse, Phi...

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Veröffentlicht in:	Chemosphere (Oxford) 2023-11, Vol.340, p.139799-139799, Article 139799
Hauptverfasser:	Rossini-Oliva, S., Montiel de La Cruz, J.M., Fernández-Espinosa, A.J., Fernández-Cañero, R., Fernández-Cabanás, V.M., Pérez Urrestarazu, L.
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Schlagworte:	air Air Pollutants - analysis Air Pollution Air Pollution, Indoor - analysis air quality Airborne particles Biodegradation, Environmental Chlorophytum Environmental Monitoring Ficus pumila glass Heath risk indoor air pollution Indoor air quality (IAQ) leaves Nature-based solutions Particle Size Particulate Matter - analysis particulates Philodendron hederaceum phytoremediation Plants species Toxic elements toxicity Tradescantia zebrina Vertical greening systems
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container_title	Chemosphere (Oxford)
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creator	Rossini-Oliva, S. Montiel de La Cruz, J.M. Fernández-Espinosa, A.J. Fernández-Cañero, R. Fernández-Cabanás, V.M. Pérez Urrestarazu, L.
description	Indoor air pollution is a serious health problem throughout the world. Plants are known to be able to reduce the effect of air pollution and improve indoor air quality (IAQ). The aim of the present study was to compare the effectiveness of four plant species (Tradescantia zebrina hort. ex Bosse, Philodendron scandens K. Koch & Sello, Ficus pumila L. and Chlorophtytum comosum (Thunb.) Jacques) planted in an active living wall (ALW) for capturing particle pollutants. The ALW was introduced in a glass chamber and exposed to large (10–40 μm) and fine (1.2–10 μm) airborne particles containing a fixed concentration of potentially toxic elements (Al, B, Cd, Co, Cr, Cu, Ni and Pb). The surface particle deposition (sPM) was estimated in the leaves from the four species and the potentially toxic element concentration in the particulate matter (PM) was measured in plants, medium culture and in the ALW support system. The distribution of different particle size fractions differed between species. The capacity to trap particles on leaf surfaces was similar among the species (4.7–13 ng cm−2) except when comparing Tradescantia and Chlorophytum with Ficus, being higher in the latter species. Differences in toxic elements accumulation capacity were observed between species depending on the elements considered. The percentage of reduction in indoor pollution using an ALW was in a range of 65–79% being similar between species. Plants were the most important component of the ALW in terms of accumulation of indoor potentially toxic elements. The data presented here could be used to model the effectiveness of ALW systems schemes in improving IAQ. [Display omitted]
doi_str_mv	10.1016/j.chemosphere.2023.139799
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Plants are known to be able to reduce the effect of air pollution and improve indoor air quality (IAQ). The aim of the present study was to compare the effectiveness of four plant species (Tradescantia zebrina hort. ex Bosse, Philodendron scandens K. Koch & Sello, Ficus pumila L. and Chlorophtytum comosum (Thunb.) Jacques) planted in an active living wall (ALW) for capturing particle pollutants. The ALW was introduced in a glass chamber and exposed to large (10–40 μm) and fine (1.2–10 μm) airborne particles containing a fixed concentration of potentially toxic elements (Al, B, Cd, Co, Cr, Cu, Ni and Pb). The surface particle deposition (sPM) was estimated in the leaves from the four species and the potentially toxic element concentration in the particulate matter (PM) was measured in plants, medium culture and in the ALW support system. The distribution of different particle size fractions differed between species. The capacity to trap particles on leaf surfaces was similar among the species (4.7–13 ng cm−2) except when comparing Tradescantia and Chlorophytum with Ficus, being higher in the latter species. Differences in toxic elements accumulation capacity were observed between species depending on the elements considered. The percentage of reduction in indoor pollution using an ALW was in a range of 65–79% being similar between species. Plants were the most important component of the ALW in terms of accumulation of indoor potentially toxic elements. The data presented here could be used to model the effectiveness of ALW systems schemes in improving IAQ. 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Plants are known to be able to reduce the effect of air pollution and improve indoor air quality (IAQ). The aim of the present study was to compare the effectiveness of four plant species (Tradescantia zebrina hort. ex Bosse, Philodendron scandens K. Koch & Sello, Ficus pumila L. and Chlorophtytum comosum (Thunb.) Jacques) planted in an active living wall (ALW) for capturing particle pollutants. The ALW was introduced in a glass chamber and exposed to large (10–40 μm) and fine (1.2–10 μm) airborne particles containing a fixed concentration of potentially toxic elements (Al, B, Cd, Co, Cr, Cu, Ni and Pb). The surface particle deposition (sPM) was estimated in the leaves from the four species and the potentially toxic element concentration in the particulate matter (PM) was measured in plants, medium culture and in the ALW support system. The distribution of different particle size fractions differed between species. The capacity to trap particles on leaf surfaces was similar among the species (4.7–13 ng cm−2) except when comparing Tradescantia and Chlorophytum with Ficus, being higher in the latter species. Differences in toxic elements accumulation capacity were observed between species depending on the elements considered. The percentage of reduction in indoor pollution using an ALW was in a range of 65–79% being similar between species. Plants were the most important component of the ALW in terms of accumulation of indoor potentially toxic elements. The data presented here could be used to model the effectiveness of ALW systems schemes in improving IAQ. [Display omitted]</description><subject>air</subject><subject>Air Pollutants - analysis</subject><subject>Air Pollution</subject><subject>Air Pollution, Indoor - analysis</subject><subject>air quality</subject><subject>Airborne particles</subject><subject>Biodegradation, Environmental</subject><subject>Chlorophytum</subject><subject>Environmental Monitoring</subject><subject>Ficus pumila</subject><subject>glass</subject><subject>Heath risk</subject><subject>indoor air pollution</subject><subject>Indoor air quality (IAQ)</subject><subject>leaves</subject><subject>Nature-based solutions</subject><subject>Particle Size</subject><subject>Particulate Matter - analysis</subject><subject>particulates</subject><subject>Philodendron hederaceum</subject><subject>phytoremediation</subject><subject>Plants</subject><subject>species</subject><subject>Toxic elements</subject><subject>toxicity</subject><subject>Tradescantia zebrina</subject><subject>Vertical greening systems</subject><issn>0045-6535</issn><issn>1879-1298</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqNkcFuGyEURVHVqnGT_kJFd92MA8MwQHaVlaSVIqWLZo0Av6mxxjAB7MSL_HtwnUbdtRLSk9C570n3IPSZkjkltD9fz90KNjFPK0gwb0nL5pQpodQbNKNSqIa2Sr5FM0I63vSc8RP0Iec1ITXM1Xt0wgQXHZF8hp5-xAKheDOOe1zio3cYRtjUr4ydmco2AbZ7bAI2rvgd4NHvfPiFH2oA-1DfMsaEIex8iuF37gJfDgO4guOA8wTOQz6Qxic8rfYlprp-6U3xMZyhd4MZM3x8mafo7ury5-Jbc3N7_X3x9aZxrOWlkWyQS-BEMds6JcG6HgQVg6LcWmdpS5ztqTBDT60S0gAxzCnbk15YZbqOnaIvx71TivdbyEVvfHYwjiZA3GbNKO9oTwlr_4m2khNBlZKiouqIuhRzTjDoKfmNSXtNiT6I0mv9lyh9EKWPomr208uZra11vCb_mKnA4ghA7WXnIelcmwyuVpdquXoZ_X-ceQZ1Za0K</recordid><startdate>202311</startdate><enddate>202311</enddate><creator>Rossini-Oliva, S.</creator><creator>Montiel de La Cruz, J.M.</creator><creator>Fernández-Espinosa, A.J.</creator><creator>Fernández-Cañero, R.</creator><creator>Fernández-Cabanás, V.M.</creator><creator>Pérez Urrestarazu, L.</creator><general>Elsevier Ltd</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>7S9</scope><scope>L.6</scope></search><sort><creationdate>202311</creationdate><title>Potentially toxic elements capture by an active living wall in indoor environments: Effect of species in air phytoremediation</title><author>Rossini-Oliva, S. ; 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subjects	air Air Pollutants - analysis Air Pollution Air Pollution, Indoor - analysis air quality Airborne particles Biodegradation, Environmental Chlorophytum Environmental Monitoring Ficus pumila glass Heath risk indoor air pollution Indoor air quality (IAQ) leaves Nature-based solutions Particle Size Particulate Matter - analysis particulates Philodendron hederaceum phytoremediation Plants species Toxic elements toxicity Tradescantia zebrina Vertical greening systems
title	Potentially toxic elements capture by an active living wall in indoor environments: Effect of species in air phytoremediation
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