A simple model for predicting water table fluctuations in a tidal marsh

Montalto, Franco; Parlange, Jean‐Yves; Steenhuis, Tammo S.

doi:10.1029/2004wr003913

Cited by 22 publications

(31 citation statements)

References 44 publications

(76 reference statements)

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“…The root zone sediments influence tidal infiltration and root water uptake and govern the mass transfer between these processes [Chapman, 1938b]. This perspective, focused on the root zone and its abiotic and biotic hydraulic properties, partially reconciles existing conceptual models of the salt marsh groundwater system as vertical flow due entirely to evapotranspiration and infiltration [Hemond and Fifield, 1982]; slow downward flow in the marsh interior feeding deep submarine groundwater discharge ; horizontal flow restricted to the channel banks, with no interior marsh flow [Harvey et al, 1987;Nuttle, 1988;Montalto et al, 2007]; or plant water uptake near channel banks controlling local water table position and unsaturated flow [Howes and Goehringer, 1994;Ursino et al, 2004;Wilson and Gardner, 2005;Li et al, 2005;Marani et al, 2006;Tosatto et al, 2009]. On the basis of the results of our detailed 3-D simulations, we conclude that each of these mechanisms is simultaneously significant in situ in different spatial regions of even a small marsh site and these different spatial regions can be usefully thought of as distinct ecohydrological zones.…”

Section: Resultsmentioning

confidence: 99%

“…(2) Vertical flow in the marsh interior feeds deep, slow flow paths beneath the marsh that contribute to submarine groundwater discharge in the coastal zone . (3) Flow is horizontal and restricted to the few meters near the channel banks affected by rapid drainage; there is no lateral flow in the marsh interior because of low sediment permeability and zero groundwater head gradient [Harvey et al, 1987;Nuttle, 1988;Montalto et al, 2007]. (4) Plant root water uptake near channel banks controls local water table position and unsaturated flow [Howes and Goehringer, 1994;Ursino et al, 2004;Wilson and Gardner, 2005;Li et al, 2005;Marani et al, 2006;Tosatto et al, 2009].…”

Section: Introductionmentioning

confidence: 99%

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Salt marsh ecohydrological zonation due to heterogeneous vegetation–groundwater–surface water interactions

Moffett¹,

Gorelick²,

McLaren³

et al. 2012

Water Resources Research

112

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[1] Vegetation zonation and tidal hydrology are basic attributes of intertidal salt marshes, but specific links among vegetation zonation, plant water use, and spatiotemporally dynamic hydrology have eluded thorough characterization. We developed a quantitative model of an intensively studied salt marsh field site, integrating coupled 2-D surface water and 3-D groundwater flow and zonal plant water use. Comparison of model scenarios with and without heterogeneity in (1) evapotranspiration rates and rooting depths, according to mapped vegetation zonation, and (2) sediment hydraulic properties from inferred geological heterogeneity revealed the coupled importance of both sources of ecohydrological variability at the site. Complex spatial variations in root zone pressure heads, saturations, and vertical groundwater velocities emerged in the model but only when both sources of ecohydrological variability were represented together and with tidal dynamics. These regions of distinctive root zone hydraulic conditions, caused by the intersection of vegetation and sediment spatial patterns, were termed ''ecohydrological zones'' (EHZ). Five EHZ emerged from different combinations of sediment hydraulic properties and evapotranspiration rates, and two EHZ emerged from local topography. Simulated pressure heads and groundwater dynamics among the EHZ were validated with field data. The model and data showed that hydraulic differences between EHZ were masked shortly after a flooding tide but again became prominent during prolonged marsh exposure. We suggest that ecohydrological zones, which reflect the combined influences of topographic, sediment, and vegetation heterogeneity and do not emphasize one influence over the others, are the fundamental spatial habitat units comprising the salt marsh ecosystem.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Salt marsh ecohydrological zonation due to heterogeneous vegetation–groundwater–surface water interactions

Moffett¹,

Gorelick²,

McLaren³

et al. 2012

Water Resources Research

112

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“…As the creek bank was vertical, the effect of a seepage face was negligible [33,46]. Therefore, the watertable exit point at the bank edge was assumed to be coupled with the tidal water level in the creek.…”

Section: Boundary and Initial Conditionsmentioning

confidence: 99%

“…Recent numerical studies examined the tidally induced pore-water flow and associated soil aeration conditions using various models including Boussinesq equation-based models [33,56], saturated flow models [15], Richards' equation-based (saturated and unsaturated flow) models [31,48,54,55,57,58,59] and air-water two-phase models [25,45]. These studies, which are mostly based on two-dimensional (2-D) cross-creek sections, aimed at quantifying the link between hydrological processes and vegetation dynamics in tidal marshes.…”

Section: Introductionmentioning

confidence: 99%

Modelling of groundwater–vegetation interactions in a tidal marsh

Xin

Kong

et al. 2013

Advances in Water Resources

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“…It should be noted that these features are not unique for the study site, but are commonly found at natural coasts [e.g. Chaney and Stone, 1996;Montalto et al, 2007]. Therefore, it is important to study how nearshore groundwater flow and solute transport are affected by these features interacting with the tidal force.…”

Section: Research Questions and Hypothesesmentioning

confidence: 99%

Groundwater dynamics in an aquifer adjacent to a coastal lagoon

Zhang¹

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Many recent studies show that submarine groundwater discharge may provide an important pathway for nutrients and contaminants to enter coastal ecosystems. To determine nutrient and contaminant loads associated with submarine groundwater discharge, there is a need for greater understanding of the flow dynamics and solute transport mechanisms in nearshore aquifers.Research is needed to quantify the effects of important factors, including terrestrial force, tidal force, beach morphology and aquifer properties, in both cross-shore and alongshore directions. Field investigations and numerical simulations were conducted in my Ph.D. research to advance our understanding of these effects. The findings from my work further demonstrate the complexity of nearshore groundwater systems and will benefit future studies of nutrient and contaminant transport and transformations associated with SGD.This research started with field investigations at a carbonate sandy beach of Muri Lagoon on the east coast of Rarotonga, Cook Island (21°15'S, 159°44'W). Two field campaigns were carried out with measurements to provide real data for studying the groundwater flow dynamics in such a system. The study was motivated by an ultimate aim to quantify the N and P transformations along the subterranean estuary and loads to the lagoon. Measurements identified significant influence of beach morphology on variations of pore water salinity in the aquifer. The interactions of tidal force and beach morphology modify the groundwater flow and discharge location, and associated solute transport. Furthermore, the field data revealed that the presence of a shallow creek modified notably the beach profiles in both the cross-shore and alongshore directions. An unexpected saline pore water zone was observed landward of the intertidal zone indicating remarkable solute transport along the shore. The field results suggested that the effects of beach morphology can be significant in determining nearshore groundwater flow and solute transport processes. The alongshore variations (bi-directional beach morphology and presence of the creek), largely neglected in the previous studies, were found to play important roles in controlling the three dimensional pore water flow in such a system.To further interpret the field data and analyse the nearshore groundwater system, numerical models were developed using a variable density and variable saturation groundwater flow code, SUTRA.Firstly, two-dimensional (2D) models were built to examine the effects of beach morphology.Different from previous studies on mild sloping beach morphology (~1/10), we focused on beaches with small slopes (~1/50 to ~1/100) and multiple slope breaks. We found that the groundwater discharge location was largely controlled by beach morphology interacting with the tidal force. The effects of varying tidal amplitude and inland heads on the discharging location were relatively small.ii Under particular conditions, the beach slope break combined with the tidal oscillation induced local circula...

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A simple model for predicting water table fluctuations in a tidal marsh

Cited by 22 publications

References 44 publications

Salt marsh ecohydrological zonation due to heterogeneous vegetation–groundwater–surface water interactions

Salt marsh ecohydrological zonation due to heterogeneous vegetation–groundwater–surface water interactions

Modelling of groundwater–vegetation interactions in a tidal marsh

Groundwater dynamics in an aquifer adjacent to a coastal lagoon

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