Kevin A. Ryan, Vanessa A. Garayburu-Caruso, Byron C. Crump, Ted Bambakidis, Peter A. Raymond, Shaoda Liu, James C. Stegen
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引用次数: 0
Abstract
Quantifying the relative influence of factors and processes controlling riverine ecosystem function is essential to predicting future conditions under global change. Dissolved organic matter (DOM) is a fundamental component of riverine ecosystems that fuels microbial food webs, influences nutrient and light availability, and represents a significant carbon flux globally. The heterogeneous nature of DOM molecular composition and its propensity for interaction (i.e., functional diversity) can characterize riverine ecosystem function across spatiotemporal scales. To investigate fundamental drivers of DOM diversity, we collected seasonal water samples from 42 nested locations within five watersheds spanning multiple watershed sizes (~ 5 to 30,000 km2) across the United States. Patterns in DOM molecular richness, aromaticity, relative abundance of N-containing formulas, and putative biochemical transformations derived from high-resolution mass spectrometry were assessed across gradients of explanatory variables associated with watershed characteristics (e.g., watershed area, water residence time, land cover). We found that putative biochemical transformations were more strongly related to explanatory variables across watersheds than common bulk DOM parameters and that watershed area, surface water residence time and derived Damköhler numbers representing DOM reactivity timescales were strong predictors of DOM diversity. The data also indicate that catchment-specific land cover factors can significantly influence DOM diversity in diverging directions. Overall, the results highlight the importance of considering water residence time and land cover when interpreting longitudinal patterns in DOM chemistry and the continued challenge of identifying generalizable drivers that are transferable across watershed and regional scales for application in Earth system models. This work also introduces a Findable Accessible Interoperable Reusable (FAIR) dataset (> 300 samples) to the community for future syntheses.
量化控制河流生态系统功能的因素和过程的相对影响对于预测全球变化下的未来条件至关重要。溶解有机物(DOM)是河流生态系统的基本组成部分,它为微生物食物网提供动力,影响养分和光的可用性,是全球重要的碳通量。DOM 分子组成的异质性及其相互作用的倾向性(即功能多样性)可以描述不同时空尺度的河流生态系统功能。为了研究 DOM 多样性的基本驱动因素,我们收集了美国多个流域(约 5 到 30,000 平方公里)内 42 个嵌套地点的季节性水样。在与流域特征(如流域面积、水体停留时间、土地覆盖)相关的解释变量梯度上,我们评估了 DOM 分子丰富度、芳香度、含 N 配方相对丰度以及通过高分辨率质谱分析得出的推定生化转化模式。我们发现,与常见的大量 DOM 参数相比,各流域的推定生化转化与解释变量的关系更为密切;流域面积、地表水停留时间和代表 DOM 反应时标的达姆克勒数是预测 DOM 多样性的有力指标。数据还表明,特定流域的土地覆被因素会在不同方向上对 DOM 多样性产生显著影响。总之,研究结果凸显了在解释 DOM 化学的纵向模式时考虑水体停留时间和土地覆被的重要性,以及在地球系统模型中应用时识别可跨流域和区域尺度转移的通用驱动因素所面临的持续挑战。这项工作还为社区引入了一个可查找、可访问、可互操作、可重复使用(FAIR)的数据集(300 个样本),用于未来的综合分析。
期刊介绍:
Biogeochemistry publishes original and synthetic papers dealing with biotic controls on the chemistry of the environment, or with the geochemical control of the structure and function of ecosystems. Cycles are considered, either of individual elements or of specific classes of natural or anthropogenic compounds in ecosystems. Particular emphasis is given to coupled interactions of element cycles. The journal spans from the molecular to global scales to elucidate the mechanisms driving patterns in biogeochemical cycles through space and time. Studies on both natural and artificial ecosystems are published when they contribute to a general understanding of biogeochemistry.