Terrestrial freshwater lenses in stable riverine settings: Occurrence and controlling factors

Werner, Adrian D.; Laattoe, Tariq

doi:10.1002/2015wr018346

Cited by 20 publications

(110 citation statements)

References 36 publications

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“…The comparison of dimensionless numbers in Table shows that laboratory freshwater lenses have a similar dimensionless lateral extent relative to the River Murray conditions reported by Werner and Laattoe []. However, compared to field conditions, the laboratory experiments involved significantly higher saltwater fluxes relative to the buoyancy force, on the basis of a .…”

Section: Discussionsupporting

confidence: 55%

“…However, compared to field conditions, the laboratory experiments involved significantly higher saltwater fluxes relative to the buoyancy force, on the basis of a . A wide range of streambed‐aquifer conditions ( b ) are apparent in the data of Werner and Laattoe [], whereas the laboratory experiments have b values in the lower range of field parameters, implying that the laboratory streambed resistance (i.e., the outlet screen) was relatively weak in the face of strong saltwater flows.…”

Section: Discussionmentioning

confidence: 99%

“…The lens extent can be obtained by combining equation with Werner and Laattoe 's [] equation , to produce:

x_{L} = \frac{1}{true(\frac{η_{b}^{2}}{η_{r}^{2}} - \frac{ρ_{f}}{ρ_{s}} true)} true[true(1 - \frac{ρ_{f}}{ρ_{s}} true) x_{b} - \frac{K B_{r}}{K_{r}} true(\frac{η_{b}^{2}}{η_{r}^{2}} - 1 true) true]

…”

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Plausibility of freshwater lenses adjacent to gaining rivers: Validation by laboratory experimentation

Werner

Kawachi

Laattoe

2016

Water Resources Research

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The occurrence of freshwater lenses in saline aquifers adjoining gaining rivers has recently been demonstrated as being theoretically possible by way of analytical solution. However, physical evidence for freshwater lenses near gaining rivers is limited largely to airborne geophysical surveys. This paper presents the first direct observations of freshwater lenses adjacent to gaining rivers, albeit at the laboratory‐scale, as validation of their plausibility. The experimental conditions are consistent with the available analytical solution, which is compared with laboratory observations of lens extent and the saltwater flow rate, for various hydraulic gradients. Numerical simulation shows that dispersion can account for the small amount of mismatch between the sharp‐interface analytical solution and laboratory measurements. Calibration and uncertainty analysis demonstrate that accurate mathematical predictions require calibration to laboratory measurements of the lens. The results provide unequivocal proof that freshwater lenses can persist despite gaining river conditions concordant with theoretical lenses predicted by the analytical solution, at least within the constraints of the experimental setup.

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Section: Discussionsupporting

confidence: 55%

Section: Discussionmentioning

confidence: 99%

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Plausibility of freshwater lenses adjacent to gaining rivers: Validation by laboratory experimentation

Werner

Kawachi

Laattoe

2016

Water Resources Research

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“…The Robin BC can be applied in groundwater modeling to represent the truncation of aquifers, whereby regions of aquifer that fall outside of the model domain are approximated by C and h ref . Additionally, flow to/from a river (in situations where the groundwater level is higher than the river bed) is often represented using Equation 5, with impedance to flow caused by the river bed included in the parameterization of C (e.g., Werner and Laattoe ).…”

Section: Robin (Type 3) Bcmentioning

confidence: 99%

Boundary Condition Nomenclature Confusion in Groundwater Flow Modeling

Jazayeri

Werner

2019

Groundwater

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“…While saline groundwater systems in semi-arid and arid environments are generally considered a problem for water resource managers, the occurrence of shallow (<100 m) brackish to saline groundwater promotes the development of localized accumulations of subsurface freshwater referred to as inland freshwater lenses (IFLs) [1][2][3]. IFLs serve as alternative freshwater resources for drinking water, livestock management, and micro-oasis agriculture in several arid and semi-arid regions including the Middle East (e.g., Kuwait, Oman, United Arab Emirates (UAE), Saudi Arabia), Australia (e.g., Murray Basin, Queensland), Central South America (e.g., Paraguay), Central Asia (e.g., Turkmenistan), Africa (e.g., Zambia, Namibia), and elsewhere with similar environmental settings [2][3][4][5][6][7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Transient Evolution of Inland Freshwater Lenses: Comparison of Numerical and Physical Experiments

Rotz

Milewski

Rasmussen

2020

Water

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Brackish to saline groundwater in arid environments encourages the development and sustainability of inland freshwater lenses (IFLs). While these freshwater resources supply much-needed drinking water throughout the Arabian Peninsula and other drylands, little is understood about their sustainability. This study presents a numerical model using the SEAWAT programming code (i.e., MODFLOW and the Modular Three-Dimensional Multispecies Transport Model (MT3DMS)) to simulate IFL transient evolution. The numerical model is based on a physical laboratory model and calibrated using results from simulations conducted in a previous study of the Raudhatain IFL in northern Kuwait. Data from three previously conducted physical model simulations were evaluated against the corresponding numerical model simulations. The hydraulic conductivities in the horizontal and vertical directions were successfully optimized to minimize the objective function of the numerical model simulations. The numerical model matched observed IFL water levels at four locations through time, as well as IFL thicknesses and lengths (R2 = 0.89, 0.94, 0.85). Predicted lens degradation times corresponded to the observed lenses, which demonstrated the utility of numerical models and physical models to assess IFL geometry and position. Improved understanding of IFL dynamics provides water-resource exploration and development opportunities in drylands throughout the Arabian Peninsula and elsewhere with similar environmental settings.

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Terrestrial freshwater lenses in stable riverine settings: Occurrence and controlling factors

Cited by 20 publications

References 36 publications

Plausibility of freshwater lenses adjacent to gaining rivers: Validation by laboratory experimentation

Plausibility of freshwater lenses adjacent to gaining rivers: Validation by laboratory experimentation

Boundary Condition Nomenclature Confusion in Groundwater Flow Modeling

Transient Evolution of Inland Freshwater Lenses: Comparison of Numerical and Physical Experiments

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