自然和工程水系统中溶解有机物性质的分子水平探索:FTICR-MS应用的重要回顾

IF 11.4 1区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Critical Reviews in Environmental Science and Technology Pub Date : 2023-01-02 DOI:10.1080/10643389.2022.2157167

Mingqi Ruan, Fengchang Wu, Fuhong Sun, Fanhao Song, Tingting Li, Chen He, Juan Jiang

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引用次数: 9

摘要

摘要溶解有机物（DOM）含有复杂的分子化合物，这些化合物在水生环境中主导着其非均匀动力学和行为。超高分辨率的傅立叶变换离子回旋共振质谱（FTICR-MS）已被证明能有效地表征水生DOM。然而，对天然和工程水系统中DOM的分子水平组成和行为的系统总结仍然不够。本研究对FTICR-MS对DOM的表征进行了批判性综述，重点介绍了天然和工程水系统中的成分多样性、化学性质、转化和动力学。首先，在互补数据集（如光谱数据）的数据解释和协作分析中引入了用于DOM表征的FTICR-MS策略。其次，基于FTICR-MS的研究结果，全面总结了DOM在自然水环境中的时空分布、光化学活性、微生物修饰和界面吸附等特征。第三，综述了不同工程处理方法引起的DOM分子变化，重点介绍了FTICR-MS结果，以突出分子变异、反应和转化。最后，我们总结了FTICR-MS的当前局限性、偏见和未来方向，以及对自然/工程衍生DOM行为的未来扩展研究。FTICR-MS的应用综述为理解水生DOM的分子化学和行为提供了有利的策略。图形摘要

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Molecular-level exploration of properties of dissolved organic matter in natural and engineered water systems: A critical review of FTICR-MS application

Abstract Dissolved organic matter (DOM) contains complex molecular compounds that dominate its heterogeneous dynamics and behaviors in aquatic environments. Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS) with ultra-high resolution has proven to be effective in characterizing aquatic DOM. However, a systematic summary of molecular-level compositions and behaviors of DOM in natural and engineered water systems remains insufficient. This study provides a critical review of DOM characterization by FTICR-MS, with emphasis on composition diversity, chemical properties, transformation, and dynamics in the natural and engineered water systems. First, FTICR-MS strategies for DOM characterization are introduced on data interpretation and collaborative analysis of complementary datasets (e.g. spectroscopic data). Second, DOM characteristics, including spatiotemporal distribution, photochemical activity, microbial modification, and interface adsorption in natural water environments were comprehensively summarized based on current FTICR-MS findings. Third, DOM molecular changes caused by different engineered treatment methods were reviewed to highlight the molecular variation, reaction, and transformation by focusing on the FTICR-MS results. Finally, we summarized current limitations, biases, and future directions of FTICR-MS, and future extended studies of natural/engineered-derived DOM behavior. This FTICR-MS application review provides favorable strategies for understanding the molecular chemistry and behaviors of aquatic DOM. Graphical Abstract

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来源期刊

Critical Reviews in Environmental Science and Technology 环境科学-环境科学

CiteScore

27.30

自引率

1.60%

发文量

审稿时长

2 months

期刊介绍： Two of the most pressing global challenges of our era involve understanding and addressing the multitude of environmental problems we face. In order to tackle them effectively, it is essential to devise logical strategies and methods for their control. Critical Reviews in Environmental Science and Technology serves as a valuable international platform for the comprehensive assessment of current knowledge across a wide range of environmental science topics. Environmental science is a field that encompasses the intricate and fluid interactions between various scientific disciplines. These include earth and agricultural sciences, chemistry, biology, medicine, and engineering. Furthermore, new disciplines such as environmental toxicology and risk assessment have emerged in response to the increasing complexity of environmental challenges. The purpose of Critical Reviews in Environmental Science and Technology is to provide a space for critical analysis and evaluation of existing knowledge in environmental science. By doing so, it encourages the advancement of our understanding and the development of effective solutions. This journal plays a crucial role in fostering international cooperation and collaboration in addressing the pressing environmental issues of our time.