Kenneth J. Anderson, John S. Kominoski, Christopher L. Osburn, Matthew A. Smith
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DOC concentrations decreased with high water depths in peat marshes and increased with high water levels in marl marshes and across mangroves, and these relationships were reproduced in freshwater peat marshes and shrub mangroves. In the highly productive riverine mangroves, cross-wavelet analysis highlighted variable relationships between DOC and water level were largely modulated by hurricane disturbances. By comparing relationships between water level and DOC concentrations with carbon sources from DOM fluorescence indices, we found that changing water sources between the dry and wet season shift DOM from algal to detrital sources in freshwater marshes, from detrital marsh to detrital mangrove sources in the brackish water ecotone, and from detrital mangrove to algal marine sources in downstream mangroves. 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引用次数: 0
摘要
由于水文压力(如海平面上升)和脉冲(如季节性水文、干扰和退化湿地的恢复)的变化,沿岸生态系统正在迅速发生变化。水位和水源的变化是沿岸湿地的主要变量,可以改变碳的浓度、来源、处理和输出。然而,来自海洋和淡水水源的水位长期上升如何影响溶解有机碳(DOC)浓度和溶解有机物(DOM)组成还不确定。我们量化了水位的长期变化对整个佛罗里达大沼泽地溶解有机碳浓度(2001-2021 年)和溶解有机物组成(2011-2021 年)的不同影响。泥炭沼泽的 DOC 浓度随着水深的增加而降低,泥灰岩沼泽和整个红树林的 DOC 浓度则随着水位的增加而增加,这些关系在淡水泥炭沼泽和灌木红树林中得到了再现。在高产的沿河红树林中,交叉小波分析强调 DOC 与水位之间的可变关系在很大程度上受飓风干扰的影响。通过比较水位和 DOC 浓度与 DOM 荧光指数碳源之间的关系,我们发现在旱季和雨季之间水源的变化会使淡水沼泽中的 DOM 从藻类转向碎屑源,咸水生态区中的 DOM 从碎屑沼泽转向碎屑红树林,下游红树林中的 DOM 从碎屑红树林转向藻类海洋源。随着气候变化和人为因素不断改变沿岸湿地的水位,整合 DOC 浓度和 DOM 组成的时空测量数据,对于更好地制约这些沿岸生态系统的碳转化和碳输出至关重要。
Shifting Sources and Fates of Carbon With Increasing Hydrologic Presses and Pulses in Coastal Wetlands
Coastal ecosystems are rapidly shifting due to changes in hydrologic presses (e.g., sea-level rise) and pulses (e.g., seasonal hydrology, disturbances, and restoration of degraded wetlands). Changing water levels and sources are master variables in coastal wetlands that can alter carbon concentrations, sources, processing, and export. Yet, how long-term increases in water levels from marine and freshwater sources influence dissolved organic carbon (DOC) concentrations and dissolved organic matter (DOM) composition is uncertain. We quantified how long-term changes in water levels are affecting DOC concentration (2001–2021) and DOM composition (2011–2021) differently across the Florida Everglades. DOC concentrations decreased with high water depths in peat marshes and increased with high water levels in marl marshes and across mangroves, and these relationships were reproduced in freshwater peat marshes and shrub mangroves. In the highly productive riverine mangroves, cross-wavelet analysis highlighted variable relationships between DOC and water level were largely modulated by hurricane disturbances. By comparing relationships between water level and DOC concentrations with carbon sources from DOM fluorescence indices, we found that changing water sources between the dry and wet season shift DOM from algal to detrital sources in freshwater marshes, from detrital marsh to detrital mangrove sources in the brackish water ecotone, and from detrital mangrove to algal marine sources in downstream mangroves. As climate change and anthropogenic drivers continue to alter water levels in coastal wetlands, integrating spatial and temporal measurements of DOC concentrations and DOM compositions is essential to better constrain the transformation and export of carbon across these coastal ecosystems.
期刊介绍:
JGR-Biogeosciences focuses on biogeosciences of the Earth system in the past, present, and future and the extension of this research to planetary studies. The emerging field of biogeosciences spans the intellectual interface between biology and the geosciences and attempts to understand the functions of the Earth system across multiple spatial and temporal scales. Studies in biogeosciences may use multiple lines of evidence drawn from diverse fields to gain a holistic understanding of terrestrial, freshwater, and marine ecosystems and extreme environments. Specific topics within the scope of the section include process-based theoretical, experimental, and field studies of biogeochemistry, biogeophysics, atmosphere-, land-, and ocean-ecosystem interactions, biomineralization, life in extreme environments, astrobiology, microbial processes, geomicrobiology, and evolutionary geobiology