河流有机质功能多样性随流域面积的增加而增加

IF 2.6 Q2 WATER RESOURCES
R. Danczak, V. Garayburu-Caruso, L. Renteria, Sophia A. McKever, Opal C. Otenburg, S. Grieger, Kyongho Son, M. Kaufman, Stephanie Fulton, J. A. Roebuck, A. Myers‐Pigg, J. Stegen
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引用次数: 0

摘要

大量溶解的有机物(DOM)每年从陆地输入输送到海洋(~0.95 Pg C /年),并经历一系列的非生物和生物反应,造成大量的CO2释放。综上所述,这些反应产生了不同的DOM特征(例如碳的标称氧化态、双键当量、化学多样性),这些特征已经证明对生物地球化学和生态系统功能有影响。然而,尽管如此,相对较少的研究关注沿河流连续体DOM化学多样性的驱动因素。在这里,我们使用超高分辨率质谱(即FTICR-MS)对从亚基马河流域的河流网络中收集的样品中的DOM进行了表征。为了将DOM化学与潜在功能联系起来,我们确定了每个样品中假定的生化转化。我们还使用不同的分子特性(例如,热力学有利性,可降解性)来计算一系列功能多样性指标。生物化学转化的多样性随着上游流域面积和土地覆被的增加而增加。这种增加也与分子式功能多样性的扩大有关。这种模式表明,当分子式在热力学或可降解性方面变得更加多样化时,生化转化的机会就会增加,从而可能形成一个自我强化的循环,在这个循环中,转化反过来增加多样性,多样性又增加转化。我们还观察到,这些模式在一定程度上与土地覆盖有关,许多土地覆盖类型(如农业、城市、森林、灌木)的出现可以扩大DOM的功能多样性。例如,我们观察到一种新的功能多样性度量与常见淡水分子式(即富含羧基的脂环分子)的相似性与城市覆盖率显著相关。这些结果表明,DOM多样性并不像河流连续统概念(River Continuum Concept)所预测的那样,沿着河流网络减少,而是受到DOM内部分子式的热力学和降解潜力以及土地覆盖模式的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Riverine organic matter functional diversity increases with catchment size
A large amount of dissolved organic matter (DOM) is transported to the ocean from terrestrial inputs each year (~0.95 Pg C per year) and undergoes a series of abiotic and biotic reactions, causing a significant release of CO2. Combined, these reactions result in variable DOM characteristics (e.g., nominal oxidation state of carbon, double-bond equivalents, chemodiversity) which have demonstrated impacts on biogeochemistry and ecosystem function. Despite this importance, however, comparatively few studies focus on the drivers for DOM chemodiversity along a riverine continuum. Here, we characterized DOM within samples collected from a stream network in the Yakima River Basin using ultrahigh-resolution mass spectrometry (i.e., FTICR-MS). To link DOM chemistry to potential function, we identified putative biochemical transformations within each sample. We also used various molecular characteristics (e.g., thermodynamic favorability, degradability) to calculate a series of functional diversity metrics. We observed that the diversity of biochemical transformations increased with increasing upstream catchment area and landcover. This increase was also connected to expanding functional diversity of the molecular formula. This pattern suggests that as molecular formulas become more diverse in thermodynamics or degradability, there is increased opportunity for biochemical transformations, potentially creating a self-reinforcing cycle where transformations in turn increase diversity and diversity increase transformations. We also observed that these patterns are, in part, connected to landcover whereby the occurrence of many landcover types (e.g., agriculture, urban, forest, shrub) could expand DOM functional diversity. For example, we observed that a novel functional diversity metric measuring similarity to common freshwater molecular formulas (i.e., carboxyl-rich alicyclic molecules) was significantly related to urban coverage. These results show that DOM diversity does not decrease along stream networks, as predicted by a common conceptual model known as the River Continuum Concept, but rather are influenced by the thermodynamic and degradation potential of molecular formula within the DOM, as well as landcover patterns.
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来源期刊
Frontiers in Water
Frontiers in Water WATER RESOURCES-
CiteScore
4.00
自引率
6.90%
发文量
224
审稿时长
13 weeks
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