Wetland Connectivity Thresholds and Flow Dynamics From Stage Measurements

McLaughlin, Daniel L.; Diamond, Jacob S.; Quintero, C.; Heffernan, James B.; Cohen, Matthew J.

doi:10.1029/2018wr024652

Cited by 20 publications

(36 citation statements)

References 57 publications

(109 reference statements)

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“…It also indicates that the topography in BICY is statistically stationary (Figure 4), resulting in conditions where a limited sampling of basin‐scale topography using a single DEM of 500 m radius, which contains multiple wetlands (pattern period ≈ 200 m), is sufficient to characterize whole‐landscape variability and patterns in elevation. Moreover, stage dynamics were highly correlated among wetlands (Figure 3) despite often large distances between them, which is consistent with our model conceptualization of distributed wetland storage acting as a single reservoir, and with recent work highlighting synchronous wetland stage and imputed spill dynamics among multiple BICY wetlands (McLaughlin et al, 2019). This, in turn, enables the fitting of a consistent “rating curve” for the stage‐discharge relationship across all wetlands (Figure 2 and Equation ).…”

Section: Resultssupporting

confidence: 91%

“…The hydroperiod varies with elevation across the landscape, with many domes being perennially inundated, while the surrounding uplands, at approximately 50 cm higher elevation, are dry most of the year (Cohen et al, 2011). Flow patterns and surface connectivity depend on stage, with connected surface flow among domes at high stage in contrast to limited wetland‐groundwater exchange at low stage (McLaughlin et al, 2019). Construction of roads for logging, oil drilling, and recreation over the last century has resulted in augmented landscape drainage through canals.…”

Section: Study Site and Experimental Descriptionmentioning

confidence: 99%

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Local Storage Dynamics of Individual Wetlands Predict Wetlandscape Discharge

Klammler

Quintero

Jawitz

et al. 2020

Water Resources Research

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Wetlands provide valuable hydrological, ecological, and biogeochemical functions, both alone and in combination with other elements comprising the wetlandscape. Understanding the processes and mechanisms that drive wetlandscape functions, as well as their sensitivity to natural and man-made alterations, requires a sound physical understanding of wetland hydrodynamics. Here, we develop and apply a single reservoir hydrologic model to a low-relief karst wetlandscape in southwest Florida (≈10 3 km 2 of Big Cypress National Preserve) using precipitation P and potential evapotranspiration PET as climatic drivers. This simple approach captures the dynamics of storage for individual wetlands across the entire wetlandscape and accurately predicts landscape discharge. Key model insights are the importance of depth-dependent extinction of evapotranspiration ET and the negligible effects of depth-dependent specific yield, the effects of which are diluted by landscape relief. We identify three phases of the wetlandscape hydrological regime: dry, wet-stagnant, and wet-flowing. The model allowed a simple steady-state analysis, which demonstrated the sudden seasonal shift between wet-stagnant and wet-flowing states, indicating a consistent threshold at P ≈ PET. Notably, stage data from any single wetland appears sufficient for accurate whole-landscape discharge prediction because of the relative homogeneity in timing and duration of local wetland hydrologic connectivity in this landscape. We also show that this method will be transferable to other wetlandscapes, where individual storage elements respond hydrologically synchronously, whereas model performance is expected to deteriorate for hydrologically more heterogeneous wetlandscapes.

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Section: Resultssupporting

confidence: 91%

Section: Study Site and Experimental Descriptionmentioning

confidence: 99%

Local Storage Dynamics of Individual Wetlands Predict Wetlandscape Discharge

Klammler

Quintero

Jawitz

et al. 2020

Water Resources Research

Self Cite

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“…While it is broadly tenable that the observed pattern is contemporary and that local divergence in elevation is induced by markedly differing weathering environments between wetlands and uplands (i.e., the positive dissolution feedbacks are clear), the negative feedbacks that inhibit dissolution features, preventing continual expansion either vertically (collapse sinkholes) or laterally are less clear. One key recent insight is that vertical expansion is limited by the absence of subsurface drainage (McLaughlin et al, ) as well as persistent shallow water table conditions. Moreover, vertical weathering rates are self‐limiting as insoluble residual materials accumulate as wetland sediment (Watts et al, ), effectively sealing carbonic acid production in the shallow sediments from unweathered bedrock at depth (Dong et al, ).…”

Section: Discussionmentioning

confidence: 99%

Scale‐Dependent Patterning of Wetland Depressions in a Low‐Relief Karst Landscape

Quintero

Cohen

2019

JGR Earth Surface

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Thousands of small wetland depression features (cypress domes) dot the low‐relief karst of Big Cypress National Preserve (BICY) in South Florida, USA. We hypothesized that these wetland depressions are organized in a regular pattern, which is atypical of wetlandscapes elsewhere. Regular patterning implies the existence of coupled feedbacks operating at different spatial scales, with local wetland depression expansion (facilitation via karst dissolution) limited by competition among adjacent depressions for finite water resources (inhibition). We sought to test the hypothesis that wetlands in BICY exhibit regular patterning, and to quantify pattern properties to evaluate competing genesis mechanisms. We tested four predictions about landscape structure and geometry using high‐resolution Light Detection and Ranging elevation data from six 2.25‐km2 domains across BICY. Specifically, we predicted (1) feature overdispersion resulting from competition between adjacent basins; (2) truncated wetland area distributions due to growth inhibition feedbacks; (3) periodicity in surface elevation indicating a characteristic pattern wavelength; and (4) elevation bimodality indicating distinct upland and wetland states. All four predictions were strongly supported. Depressions were significantly overdispersed and efficiently fill the landscape, generating hexagonal patterning. Wetland areas followed truncated power law scaling, indicating incremental constraints on basin expansion, in contrast to depression areas elsewhere. Variogram and radial spectrum analyses revealed clear periodicity (~150‐ to 250‐m wavelength) in surface elevations. Finally, surface elevations were consistently bimodal with elevation divergence of 10 to 40 cm. Regular patterning of wetland depressions across BICY is clear, implying long‐term biogeomorphic control on landform structure in this karst landscape.

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“…Recent research provides some evidence that catchment‐scale RWU strategies could be derived from surface water observations. McLaughlin et al () observed evapotranspiration signals within wetland stage measurements. Similarly, Tashie et al () demonstrated that streamflow recessions in a headwater catchment in the southern Appalachian Mountains reflected both gravity‐driven groundwater outflow to surface waters as well as forest transpiration.…”

Section: Introductionmentioning

confidence: 99%

Understanding Catchment‐Scale Forest Root Water Uptake Strategies Across the Continental United States Through Inverse Ecohydrological Modeling

Knighton

Singh

Evaristo

2020

Geophysical Research Letters

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Trees influence the partitioning of water between catchment water yield and evapotranspiration through mediation of soil water via root water uptake (RWU). Recent research has estimated the depth of RWU for a variety of tree species at plot scales with measurements of stable isotopes in water and sap flux. Though informative, there are some challenges bridging the gap between plot‐ and catchment‐scale water fluxes. We estimated catchment‐scale tree RWU behavior for 139 forested catchments across the continental United States from continuous streamflow records with inverse ecohydrological modeling. Our catchment‐scale RWU estimates agreed well with existing plot‐scale research. Monoculture catchments dense with trees reliant on shallow soil water exhibited reduced transpiration losses compared to deep‐rooted and mixed‐species forests within the Budkyo framework. This research highlights the importance of representing plant characteristics that define RWU control of transpiration in land surface and earth systems models.

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Wetland Connectivity Thresholds and Flow Dynamics From Stage Measurements

Cited by 20 publications

References 57 publications

Local Storage Dynamics of Individual Wetlands Predict Wetlandscape Discharge

Local Storage Dynamics of Individual Wetlands Predict Wetlandscape Discharge

Scale‐Dependent Patterning of Wetland Depressions in a Low‐Relief Karst Landscape

Understanding Catchment‐Scale Forest Root Water Uptake Strategies Across the Continental United States Through Inverse Ecohydrological Modeling

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