长江溶解有机物生物降解性的不可忽略的同源贡献

IF 4.8 Q1 ENVIRONMENTAL SCIENCES
You Wu, Lize Meng, Yiru Pan, Shenyan Zhang, Zijun Wu, Chu Zhao, Guangrui Yang, Jingyang Xu, Yue Ren, Tao Huang, Zihao Bian, Qihao Jiang*, Jian Zhou, Hao Yang, Zhaoyuan Yu, Linwang Yuan, Hailong Liu and Changchun Huang*, 
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引用次数: 0

摘要

河流中的生物可降解溶解有机碳(BDOC)对于调节从陆地到海洋的碳传输过程中的有机碳降解和温室气体排放至关重要。生物可降解有机碳与河流溶解有机物(DOM)的生物可利用性密切相关。然而,大江大河中溶解有机物的主要来源--异源溶解有机物的生物可利用性仍不清楚。本研究采用稳定碳同位素、激发-发射基质荧光和傅立叶变换离子回旋共振质谱分析方法,研究了长江中 DOM 来源对 DOM 生物利用率的影响。结果表明,BDOC 是长江溶解有机碳(DOC)的重要组成部分(29.82 ± 15.30%)。自生源占生物可吸收 DOM 总量的 38.21 ± 25.42%,呈现饱和特征,主要包括 CHOP 和 CHOS 化合物。令人惊讶的是,异源生物可吸收 DOM 占 34.41 ± 27.53%,强调了相对较高的氧化态和芳香性,并含有丰富的杂原子成分。三峡大坝地区长期的水体滞留促进了同源生物可吸收 DOM 的降解,而下游人类活动的增加则导致了自源生物可吸收 DOM 的积累。这项研究强调了同源物对溶解氧生物可降解性的贡献,并表明陆源输入量的持续增加会增强河流的 BDOC,从而影响河流的二氧化碳释放。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Non-Negligible Allochthonous Contributions to Dissolved Organic Matter Biodegradability in the Yangtze River

Non-Negligible Allochthonous Contributions to Dissolved Organic Matter Biodegradability in the Yangtze River

Biodegradable dissolved organic carbon (BDOC) in rivers is crucial for regulating organic carbon degradation and greenhouse gas emissions during carbon transport from land to ocean. BDOC is closely linked to the biolability of riverine dissolved organic matter (DOM). However, the bioavailability of allochthonous DOM, the dominant source of DOM in large rivers, remains unclear. In this study, stable carbon isotope, excitation–emission matrix fluorescence, and Fourier transform ion cyclotron resonance mass spectrometry analyses were performed to investigate the effects of DOM sources on DOM bioavailability in the Yangtze River. The results indicate that BDOC is an important fraction of dissolved organic carbon (DOC) in the Yangtze River (29.82 ± 15.30%). Autochthonous source contributed 38.21 ± 25.42% to total biolabile DOM, exhibited saturated characteristics, and primarily comprising CHOP and CHOS compounds. Surprisingly, allochthonous biolabile DOM accounted for 34.41 ± 27.53%, emphasizing relatively high oxidation state and aromaticity with enriched heteroatomic contributions. Prolonged water retention in the Three Gorges Dam region promotes allochthonous biolabile DOM degradation, whereas increased human activity downstream leads to autochthonous biolabile DOM accumulation. This study highlights allochthonous contributions to DOM biolability and indicates that continued increases in terrigenous inputs can enhance riverine BDOC, thereby influencing CO2 release from rivers.

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