Spatiotemporal Patterns and Mechanisms of Periphytic Biofilm-Induced Fe Accumulation in Paddy Fields

IF 7.4 Q1 ENGINEERING, ENVIRONMENTAL

ACS ES&T engineering Pub Date : 2024-10-07 DOI:10.1021/acsestengg.4c0048410.1021/acsestengg.4c00484

Jing Tao, Guanghui Liu, Ying Xu, Junzhuo Liu, Pengfei Sun* and Yonghong Wu*,

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Abstract

A high content of iron (Fe) within paddy ecosystems can poison rice plants or increase the risk of migration from rice fields to pollute adjacent rivers and streams. Here, we found that paddy field periphytic biofilms, ubiquitous microbial aggregates that grow on the soil surface, function as potential in situ biointerceptors via Fe accumulation. This is because periphytic biofilms were discovered, according to a spatiotemporal distribution field survey, to have a high capacity for Fe accumulation. The Fe contents in the paddy field periphytic biofilms ranged from 12.40 to 50.60 g/kg at spatial distribution and from 18.24 to 56.53 g/kg at temporal distribution, revealing significant spatiotemporal patterns consistent with the Fe concentration in soils. Extracellular polymeric substance-dominated abiotic accumulation may be a key mechanism that accounts for no less than 30–46% of the Fe accumulation in periphytic biofilms. Periphytic biofilms that accumulate Fe hold potential in intercepting their migration from paddy soil to adjacent ecosystems, thus alleviating Fe poisoning in rice plants as well as minimizing pollution in the adjoining fields. Our findings suggest that the application of periphytic biofilms is a promising engineering measure for alleviating the negative effects of excessive Fe in paddy fields.

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来源期刊

ACS ES&T engineering ENGINEERING, ENVIRONMENTAL-

CiteScore

8.50

自引率

0.00%

发文量

期刊介绍： ACS ES&T Engineering publishes impactful research and review articles across all realms of environmental technology and engineering, employing a rigorous peer-review process. As a specialized journal, it aims to provide an international platform for research and innovation, inviting contributions on materials technologies, processes, data analytics, and engineering systems that can effectively manage, protect, and remediate air, water, and soil quality, as well as treat wastes and recover resources. The journal encourages research that supports informed decision-making within complex engineered systems and is grounded in mechanistic science and analytics, describing intricate environmental engineering systems. It considers papers presenting novel advancements, spanning from laboratory discovery to field-based application. However, case or demonstration studies lacking significant scientific advancements and technological innovations are not within its scope. Contributions containing experimental and/or theoretical methods, rooted in engineering principles and integrated with knowledge from other disciplines, are welcomed.