Synergistic promotion mechanism and structure-function relationship of nonmetallic atoms doped carbon nanodots driving Tagetes patula L. to remediate cadmium-contaminated soils

IF 2.9 Q2 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH
Guling Xing, Qiong Chen, Yiwen Sun, Jianquan Wang, Junbo Zhou, Lanxuan Sun, Quyu Shu, Jing Zhang, Mei Yan
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Abstract

Phytoremediation is an economical and effective strategy to remove cadmium (Cd) from polluted environments. To improve its efficiency, nanotechnology has been proposed to collaborate with hyperaccumulators in the remediation of Cd-polluted soils. However, the intricate structure-function relationship and the underlying regulatory mechanisms by which nanomaterials regulate Cd migration and conversion within the soil-plant system remained unrevealed. In this study, functional carbon nanodots (FCNs) were modified by doping with nitrogen and (or) sulfur elements. The synthesized nonmetallic atoms-doped FCNs were utilized to investigate their structure-function relationship and the regulatory mechanisms underlying their role in the phytoremediation of Cd-polluted soils by Tagetes patula L. FCNs-based nanomaterials can regulate the migration and bioaccumulation of Cd in the soil-plant system, which exhibits an obvious structural dependency. Specifically, the synergistic application of sulfur doped FCNs and Tagetes patula L. had the highest Cd removal efficiency of 53.2%, which was 20.1% higher than Tagetes patula L. alone. The uptake and migration of Cd in the soil-plant system are regulated by FCNs-based nanomaterials through both direct and indirect mechanisms, involving interfacial reactions, plant physiology regulation and environmental influence. This study not only sheds light on the fate of FCNs-based nanomaterials and Cd in the soil-plant system, but also provides innovative nanotools for reinforcing phytoremediation efficiency in contaminated soils.

Abstract Image

非金属原子掺杂碳纳米点驱动万寿菊修复镉污染土壤的协同促进机制及结构功能关系
植物修复是清除受污染环境中的镉(Cd)的一种经济而有效的策略。为了提高其效率,有人提出利用纳米技术与高积累生物合作,对受镉污染的土壤进行修复。然而,纳米材料在土壤-植物系统中调控镉迁移和转化的复杂结构-功能关系和内在调控机制仍未被揭示。本研究通过掺杂氮元素和(或)硫元素对功能碳纳米点(FCNs)进行了修饰。利用合成的掺杂非金属元素的功能碳纳米管,研究了其结构与功能的关系及其在万寿菊(Tagetes patula L.)对镉污染土壤的植物修复中的调控机制。 以功能碳纳米管为基础的纳米材料可以调控镉在土壤-植物系统中的迁移和生物累积,并表现出明显的结构依赖性。具体而言,掺硫FCNs与万寿菊的协同应用对镉的去除率最高,达到53.2%,比单独应用高出20.1%。基于 FCNs 的纳米材料通过界面反应、植物生理调控和环境影响等直接和间接机制调控土壤-植物系统对镉的吸收和迁移。该研究不仅揭示了FCNs基纳米材料和镉在土壤-植物系统中的归宿,还为提高污染土壤的植物修复效率提供了创新的纳米工具。
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来源期刊
ACS Chemical Health & Safety
ACS Chemical Health & Safety PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH-
CiteScore
3.10
自引率
20.00%
发文量
63
期刊介绍: The Journal of Chemical Health and Safety focuses on news, information, and ideas relating to issues and advances in chemical health and safety. The Journal of Chemical Health and Safety covers up-to-the minute, in-depth views of safety issues ranging from OSHA and EPA regulations to the safe handling of hazardous waste, from the latest innovations in effective chemical hygiene practices to the courts'' most recent rulings on safety-related lawsuits. The Journal of Chemical Health and Safety presents real-world information that health, safety and environmental professionals and others responsible for the safety of their workplaces can put to use right away, identifying potential and developing safety concerns before they do real harm.
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