Characterization of Storm Flow Dynamics of Headwater Streams in the South Carolina Lower Coastal Plain<sup>1</sup>

Epps, Thomas H.; Hitchcock, Daniel R.; Jayakaran, Anand D.; Loflin, Drake R.; Williams, Thomas M.; Amatya, Devendra M.

doi:10.1111/jawr.12000

Cited by 25 publications

(38 citation statements)

References 17 publications

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“…Differences in water table position has been shown to be a primary cause for variability in the relationship between rainfall and runoff (Epps et al, 2013;La Torre Torres et al, 2011;Harder et al, 2007;Young and Klawitter, 1968). This high variability is probably responsible for the low R 2 values found by MOSUM analysis, although using rainfall measurements from the relatively distal Santee headquarters rain gauge (refer Fig.…”

Section: A D Jayakaran Et Al: Hurricane Impacts On a Pair Of Coastmentioning

confidence: 99%

“…Storm runoff varies widely, from none to over 70 % of rainfall (Epps et al, 2013), which is believed to be related to soil water and depression storage. In low-gradient forested watersheds, we anticipate an even greater coupling of transpirative and soil water dynamics in runoff generation processes (Amatya et al, 1996;Slattery et al, 2006;Sun et al, 2010;Amatya and Skaggs, 2011;Dai et al, 2011;Skaggs et al, 2011;Tian et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Hurricane impacts on a pair of coastal forested watersheds: implications of selective hurricane damage to forest structure and streamflow dynamics

Jayakaran

Williams

Ssegane

et al. 2014

Hydrol. Earth Syst. Sci.

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Abstract. Hurricanes are infrequent but influential disruptors of ecosystem processes in the southeastern Atlantic and Gulf coasts. Every southeastern forested wetland has the potential to be struck by a tropical cyclone. We examined the impact of Hurricane Hugo on two paired coastal South Carolina watersheds in terms of streamflow and vegetation dynamics, both before and after the hurricane's passage in 1989. The study objectives were to quantify the magnitude and timing of changes including a reversal in relative streamflow difference between two paired watersheds, and to examine the selective impacts of a hurricane on the vegetative composition of the forest. We related these impacts to their potential contribution to change watershed hydrology through altered evapotranspiration processes. Using over 30 years of monthly rainfall and streamflow data we showed that there was a significant transformation in the hydrologic character of the two watersheds -a transformation that occurred soon after the hurricane's passage. We linked the change in the rainfall-runoff relationship to a catastrophic change in forest vegetation due to selective hurricane damage. While both watersheds were located in the path of the hurricane, extant forest structure varied between the two watersheds as a function of experimental forest management techniques on the treatment watershed. We showed that the primary damage was to older pines, and to some extent larger hardwood trees. We believe that lowered vegetative water use impacted both watersheds with increased outflows on both watersheds due to loss of trees following hurricane impact. However, one watershed was able to recover to pre hurricane levels of evapotranspiration at a quicker rate due to the greater abundance of pine seedlings and saplings in that watershed.

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Section: A D Jayakaran Et Al: Hurricane Impacts On a Pair Of Coastmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Hurricane impacts on a pair of coastal forested watersheds: implications of selective hurricane damage to forest structure and streamflow dynamics

Jayakaran

Williams

Ssegane

et al. 2014

Hydrol. Earth Syst. Sci.

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“…Previous work within these study watersheds determined breakpoint water table elevations for measures of outflow and runoff at each of these watersheds above which runoff generation increased sharply. These breakpoints were in the range of 3.25–3.5 m above sea level at UDC and 8.5–8.97 m above sea level at WS80 (Epps et al ., ). Figure demonstrates that the trend in CNs plotted by antecedent water table elevation approximately intersects the CN‐II and mean storm event CN lines within these water table elevation ranges at each of the watersheds.…”

Section: Resultsmentioning

confidence: 99%

“…(Left) Upper Debidue Creek ( UDC ) Watershed and (Right) Watershed 80 (WS80) Delineations and Monitoring Networks, Including Outflow and Rainfall Gages, and Water Table Wells ( WR 66/P1 and Well H, respectively) (Epps et al ., ).…”

Section: Methodsmentioning

confidence: 99%

Curve Number Derivation for Watersheds Draining Two Headwater Streams in Lower Coastal Plain South Carolina, USA

Epps

Hitchcock

Jayakaran

et al. 2013

J American Water Resour Assoc

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The objective of this study was to assess curve number (CN) values derived for two forested headwater catchments in the Lower Coastal Plain (LCP) of South Carolina using a three-year period of storm event rainfall and runoff data in comparison with results obtained from CN method calculations. Derived CNs from rainfall/runoff pairs ranged from 46 to 90 for the Upper Debidue Creek (UDC) watershed and from 42 to 89 for the Watershed 80 (WS80). However, runoff generation from storm events was strongly related to water table elevation, where seasonally variable evapotranspirative wet and dry moisture conditions persist. Seasonal water table fluctuation is independent of, but can be compounded by, wet conditions that occur as a result of prior storm events, further complicating flow prediction. Runoff predictions for LCP first-order watersheds do not compare closely to measured flow under the average moisture condition normally associated with the CN method. In this study, however, results show improvement in flow predictions using CNs adjusted for antecedent runoff conditions and based on water table position. These results indicate that adaptations of CN model parameters are required for reliable flow predictions for these LCP catchments with shallow water tables. Low gradient topography and shallow water table characteristics of LCP watersheds allow for unique hydrologic conditions that must be assessed and managed differently than higher gradient watersheds.(KEY TERMS: surface water/groundwater interactions; runoff; stormwater management; watershed management; curve number method; first-order streams.)

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“…The potential connection between the shallow aquifers and the deeper, regionally-confined aquifers, that in-part support many large communities, is poorly understood. Although variable shallow water table dynamics driven by the interaction between rainfall and the water table dominate the streamflow as saturation excess runoff in these coastal forests [28,39,41,45,[47][48][49], earlier hydrological water balance studies on forest watersheds within the Francis Marion National Forest, based on field measurements [39] and model validation studies [50,51], assumed a negligible interaction between shallow and deep aquifers or no deep seepage losses. However, recent work investigating shallow groundwater recharge in the lower coastal plain estimated an average annual recharge rate to the water table aquifer of about 10% of the total precipitation [26].…”

Section: The Role Of Groundwater As a Driver On Forest Conditionsmentioning

confidence: 99%

Coastal Forests and Groundwater: Using Case Studies to Understand the Effects of Drivers and Stressors for Resource Management

2017

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Abstract:Forests are receiving more attention for the ecosystem goods and services they provide and the potential change agents that may affect forest health and productivity. Highlighting case examples from coastal forests in South Carolina, USA, we describe groundwater processes with respect to stressors and potential responses of a wetland-rich forested landscape, the roles that this area has served, and the need for water resource data to inform forest management decisions. Forested lands in the southeastern U.S. coastal plain provide a rich set of goods and services for the region, and in one case, the Francis Marion National Forest acts as a buffer to urbanization from the surrounding Charleston metropolitan area. Information from two decades of studies in the forested watersheds there may inform scientists and managers in other coastal forested systems. The common hydrological theme in this region, which has a higher average annual rainfall (1370 mm) than the annual potential evapotranspiration (PET = 1135 mm), is a shallow (<3 m) water table condition that supports a large range of natural wetlands and also creates management challenges across the region. Modest changes in the position of the water table can lead to either groundwater flooding and concomitant management challenges for forest services, or ecosystem stresses related to dry conditions in wetlands during times of below-normal precipitation or due to groundwater withdrawal. Development pressures have also stressed forest resources through the extraction of materials such as timber and sand mining, and the conversion to housing construction materials. These areas are also targeted for land development, to meet housing demands. In this paper, we discuss the role of groundwater in coastal forests and highlight opportunities for collaborative studies to better inform forest resource management.

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Characterization of Storm Flow Dynamics of Headwater Streams in the South Carolina Lower Coastal Plain¹

Cited by 25 publications

References 17 publications

Hurricane impacts on a pair of coastal forested watersheds: implications of selective hurricane damage to forest structure and streamflow dynamics

Hurricane impacts on a pair of coastal forested watersheds: implications of selective hurricane damage to forest structure and streamflow dynamics

Curve Number Derivation for Watersheds Draining Two Headwater Streams in Lower Coastal Plain South Carolina, USA

Coastal Forests and Groundwater: Using Case Studies to Understand the Effects of Drivers and Stressors for Resource Management

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Characterization of Storm Flow Dynamics of Headwater Streams in the South Carolina Lower Coastal Plain1

Cited by 25 publications

References 17 publications

Hurricane impacts on a pair of coastal forested watersheds: implications of selective hurricane damage to forest structure and streamflow dynamics

Hurricane impacts on a pair of coastal forested watersheds: implications of selective hurricane damage to forest structure and streamflow dynamics

Curve Number Derivation for Watersheds Draining Two Headwater Streams in Lower Coastal Plain South Carolina, USA

Coastal Forests and Groundwater: Using Case Studies to Understand the Effects of Drivers and Stressors for Resource Management

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Characterization of Storm Flow Dynamics of Headwater Streams in the South Carolina Lower Coastal Plain¹