Biochar from constructed wetland biomass waste: A review of its potential and challenges

Constructed wetland is considered a promising approach for water remediation due to its high efficiency, low operation costs, and ecological benefits, but the large amounts of wetland plant biomass need to be properly harvested and utilized. Recently, wetland plant derived biochar has drawn extensiv...

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Veröffentlicht in:	Chemosphere (Oxford) 2022-01, Vol.287, p.132259-132259, Article 132259
Hauptverfasser:	Cui, Xiaoqiang, Wang, Jiangtao, Wang, Xutong, Khan, Muhammad Bilal, Lu, Min, Khan, Kiran Yasmin, Song, Yingjin, He, Zhenli, Yang, Xiaoe, Yan, Beibei, Chen, Guanyi
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Sprache:	eng
Schlagworte:	Aquatic plant Biochar Carbon sequestration constructed wetlands economic feasibility energy feedstocks gasification heat heavy metals hydrothermal carbonization phytomass pyrolysis remediation soil soil amendments Soil improvement Sorption toxicity wastes wetland plants
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container_title	Chemosphere (Oxford)
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creator	Cui, Xiaoqiang Wang, Jiangtao Wang, Xutong Khan, Muhammad Bilal Lu, Min Khan, Kiran Yasmin Song, Yingjin He, Zhenli Yang, Xiaoe Yan, Beibei Chen, Guanyi
description	Constructed wetland is considered a promising approach for water remediation due to its high efficiency, low operation costs, and ecological benefits, but the large amounts of wetland plant biomass need to be properly harvested and utilized. Recently, wetland plant derived biochar has drawn extensive attention owing to its application potential. This paper provides an updated review on the production and characteristics of wetland plant derived biochar, and its utilization in soil improvement, carbon sequestration, environmental remediation, and energy production. In comparison to hydrothermal carbonization and gasification, pyrolysis is a more common technique to convert wetland plant to biochar. Characteristics of wetland plant biochars varied with plant species, growth environment of plant, and preparation conditions. Wetland plant biochar could be a qualified soil amendment owing to its abundant nutrients. Notably, wetland plant biochar exhibited considerable sorption capacity for various inorganic and organic contaminants. However, the potentially toxic substances (e.g. heavy metal and polycyclic aromatic hydrocarbons) retained in wetland plant biochar should be noticed before large-scale application. To overcome the drawbacks from the scattered distribution, limited productivity, and seasonal operation of constructed wetlands, the economic feasibility of wetland plant biochar production system could be improved via using mobile pyrolysis unit, utilizing local waste heat, and exploiting all the byproducts. Future challenges in the production and application of wetland plant derived biochar include the continuous supply of feedstock and proper handling of potentially hazardous components in the biochar. [Display omitted] •Wetland plant biochar has potential in pollutant sorption and soil improvement.•The risk of heavy metals in wetland plant biochar should be noticed.•Optimizations in production and application of wetland plant biochar are proposed.
doi_str_mv	10.1016/j.chemosphere.2021.132259
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Recently, wetland plant derived biochar has drawn extensive attention owing to its application potential. This paper provides an updated review on the production and characteristics of wetland plant derived biochar, and its utilization in soil improvement, carbon sequestration, environmental remediation, and energy production. In comparison to hydrothermal carbonization and gasification, pyrolysis is a more common technique to convert wetland plant to biochar. Characteristics of wetland plant biochars varied with plant species, growth environment of plant, and preparation conditions. Wetland plant biochar could be a qualified soil amendment owing to its abundant nutrients. Notably, wetland plant biochar exhibited considerable sorption capacity for various inorganic and organic contaminants. However, the potentially toxic substances (e.g. heavy metal and polycyclic aromatic hydrocarbons) retained in wetland plant biochar should be noticed before large-scale application. To overcome the drawbacks from the scattered distribution, limited productivity, and seasonal operation of constructed wetlands, the economic feasibility of wetland plant biochar production system could be improved via using mobile pyrolysis unit, utilizing local waste heat, and exploiting all the byproducts. Future challenges in the production and application of wetland plant derived biochar include the continuous supply of feedstock and proper handling of potentially hazardous components in the biochar. 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To overcome the drawbacks from the scattered distribution, limited productivity, and seasonal operation of constructed wetlands, the economic feasibility of wetland plant biochar production system could be improved via using mobile pyrolysis unit, utilizing local waste heat, and exploiting all the byproducts. Future challenges in the production and application of wetland plant derived biochar include the continuous supply of feedstock and proper handling of potentially hazardous components in the biochar. 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subjects	Aquatic plant Biochar Carbon sequestration constructed wetlands economic feasibility energy feedstocks gasification heat heavy metals hydrothermal carbonization phytomass pyrolysis remediation soil soil amendments Soil improvement Sorption toxicity wastes wetland plants
title	Biochar from constructed wetland biomass waste: A review of its potential and challenges
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