Unlocking the potential of hydrogen isotopes (δ2H) in tracing riverine particulate organic matter sources and dynamics

IF 2 3区环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES

Aquatic Sciences Pub Date : 2024-10-24 DOI:10.1007/s00027-024-01127-1

F. Ferchiche, C. Liénart, N. Savoye, L. I Wassenaar

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Abstract

This study explores the efficacy of hydrogen isotopes in tracing the origins and dynamics of particulate organic matter (POM) in the Loire River, employing a novel dual vapor equilibration method to measure its non-exchangeable hydrogen (δ²H_n). By integrating δ²H_n with traditional carbon (δ¹³C) and nitrogen (δ¹⁵N) isotopes and C/N ratios of POM, we compared the ecological information using multivariate analyses. Fortnightly river sampling over 3 years showed seasonal patterns in the δ²H_n values of POM, highlighting two primary POM end-members: phytoplankton and terrestrial matter. Bayesian mixing models confirmed that using δ²H_n as a tracer effectively discriminated these riverine POM end-members, with phytoplankton predominating in spring–summer and terrestrial matter in winter. Redundancy analyses revealed the main environmental drivers of POM composition, identifying significant correlations between the POM sources, chlorophyll a, suspended particulate matter, and river discharge. Our findings demonstrate that δ²H_n, alone or combined with δ¹³C, δ¹⁵N, or N/C ratio, provided a new robust tracer for POM source dynamics, thereby offering valuable insights into riverine biogeochemical cycles and ecosystem functioning. Our study underscores the novel potential of δ²H_n as a tool in environmental and ecological research, advocating for its broader application across various aquatic ecosystems to enhance our understanding of organic matter dynamics.

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释放氢同位素（δ2H）在追踪河流颗粒有机物来源和动态方面的潜力

本研究探索了氢同位素在追踪卢瓦尔河颗粒有机物（POM）的来源和动态方面的功效，采用了一种新颖的双蒸汽平衡法来测量其不可交换氢（δ2Hn）。通过将δ2Hn 与传统的碳（δ13C）和氮（δ15N）同位素以及 POM 的 C/N 比值相结合，我们利用多元分析比较了生态信息。3 年中每两周一次的河流取样显示了 POM δ2Hn 值的季节性模式，突出了两种主要的 POM 最终成员：浮游植物和陆地物质。贝叶斯混合模型证实，使用δ2Hn 作为示踪剂可有效区分这些河流 POM 最终成员，浮游植物在春夏季占主导地位，而陆地物质则在冬季占主导地位。冗余分析揭示了 POM 组成的主要环境驱动因素，确定了 POM 来源、叶绿素 a、悬浮颗粒物和河流排水量之间的显著相关性。我们的研究结果表明，δ2Hn（单独或与δ13C、δ15N或N/C比值相结合）为POM来源动态提供了一种新的可靠示踪剂，从而为了解河流生物地球化学循环和生态系统功能提供了宝贵的信息。我们的研究强调了δ2Hn作为环境和生态研究工具的新潜力，主张将其更广泛地应用于各种水生生态系统，以增进我们对有机物动态的了解。

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来源期刊

Aquatic Sciences 环境科学-海洋与淡水生物学

CiteScore

3.90

自引率

4.20%

发文量

审稿时长

1 months

期刊介绍： Aquatic Sciences – Research Across Boundaries publishes original research, overviews, and reviews dealing with aquatic systems (both freshwater and marine systems) and their boundaries, including the impact of human activities on these systems. The coverage ranges from molecular-level mechanistic studies to investigations at the whole ecosystem scale. Aquatic Sciences publishes articles presenting research across disciplinary and environmental boundaries, including studies examining interactions among geological, microbial, biological, chemical, physical, hydrological, and societal processes, as well as studies assessing land-water, air-water, benthic-pelagic, river-ocean, lentic-lotic, and groundwater-surface water interactions.