Submarine groundwater discharge and associated chemical input to a coastal sea

Li, Ling; Barry, David Andrew; Stagnitti, Frank; Parlange, J.‐Y.

doi:10.1029/1999wr900189

Cited by 415 publications

(304 citation statements)

References 11 publications

(13 reference statements)

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“…While wave periods typically range from a few to tens of seconds in the nearshore zone, wave height also varies over long time scales with intensified wave conditions occurring, for 19 instance, in response to offshore storms. Waves drive large volumes of water exchange across the CUA-ocean interface [Li et al, 1999]. It is challenging to quantify wave-driven recirculation from field data alone, but estimates have been provided through numerical studies [e.g., Xin et al, 2010;Bakhtyar et al, 2011;Geng et al, 2014;Robinson et al, 2014;Xin et al, 2014].…”

Section: Wavesmentioning

confidence: 99%

“…Field and numerical studies quantified the tidal effect on SGD and showed that tide-induced recirculation can represent a major portion of total SGD [e.g., Li et al, 1999;Taniguchi, 2002;Robinson et al, 2007c;Li et al, 2009]. Seawater infiltration into an aquifer occurs on the rising tide and exfiltration (saline SGD) on the ebbing tide [Robinson et al, 1998;Sholkovitz et al, 2003;Robinson et al, 2007c].…”

Section: Tidesmentioning

confidence: 99%

“…In early work, SGD was taken to be a linear sum of (independent) fluxes estimated based on the various inland and oceanic forces [Li et al, 1999;Taniguchi et al, 2002;Burnett et al, 2006]. Indeed, these forces and associated fluxes have been often studied numerically in isolation as discussed earlier.…”

Section: Interacting Effects Among Forcingmentioning

confidence: 99%

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Groundwater dynamics in subterranean estuaries of coastal unconfined aquifers: Controls on submarine groundwater discharge and chemical inputs to the ocean

Robinson¹,

Xin²,

Santos³

et al. 2018

Advances in Water Resources

198

138

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Sustainable coastal resource management requires sound understanding of interactions between coastal unconfined aquifers and the ocean as these interactions influence the flux of chemicals to the coastal ocean and the availability of fresh groundwater resources. The importance of submarine groundwater discharge in delivering chemical fluxes to the coastal ocean and the critical role of the subterranean estuary (STE) in regulating these fluxes is well recognized. STEs are complex and dynamic systems exposed to various physical, hydrological, geological, and chemical conditions that act on disparate spatial and temporal scales. This paper provides a review of the effect of factors that influence flow and salt transport in STEs, evaluates current understanding on the interactions between these influences, and synthesizes understanding of drivers of nutrient, carbon, greenhouse gas, metal and organic contaminant fluxes to the ocean.Based on this review, key research needs are identified. While the effects of density and tides are well understood, episodic and longer-period forces as well as the interactions between multiple influences remain poorly understood. Many studies continue to focus on idealized nearshore aquifer systems and future work needs to consider real world complexities such as geological heterogeneities, and non-uniform and evolving alongshore and cross-shore morphology. There is also a significant need for multidisciplinary research to unravel the interactions between physical and biogeochemical processes in the STE, as most existing studies treat these processes in isolation. Better understanding of this complex and dynamic system can improve sustainable management of coastal water resources under the influence of anthropogenic pressures and climate change.

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Section: Wavesmentioning

confidence: 99%

Section: Tidesmentioning

confidence: 99%

See 1 more Smart Citation

Groundwater dynamics in subterranean estuaries of coastal unconfined aquifers: Controls on submarine groundwater discharge and chemical inputs to the ocean

Robinson¹,

Xin²,

Santos³

et al. 2018

Advances in Water Resources

198

138

View full text Add to dashboard Cite

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“…[3] Time-averaging of the beach groundwater response to wave forcing reveals a localized seaward directed circulation cell [Longuet-Higgins, 1983; which has implications for the availability and quality of coastal groundwater resources and for the fate of contaminants [e.g., Li et al, 1999;Moore, 1999]. The dynamics of the water table exit point on the beach face have also been linked to the distribution of interstitial macrofauna [e.g., McArdle and McLachlan, 1991] and to aeolian sediment transport on beaches [e.g., Jackson and Nordstrom, 1997].…”

Section: Introductionmentioning

confidence: 99%

Swash‐aquifer interaction in the vicinity of the water table exit point on a sandy beach

et al. 2006

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[1] The coupling of sandy beach aquifers with the swash zone in the vicinity of the water table exit point is investigated through simultaneous measurements of the instantaneous shoreline (swash front) location, pore pressures and the water table exit point. The field observations reveal new insights into swash-aquifer coupling not previously gleaned from measurements of pore pressure only. In particular, for the case where the exit point is seaward of the observation point, the pore pressure response is correlated with the distance between the exit point and the shoreline in that when the distance is large the rate of pressure drop is fast and when the distance is small the rate decreases. The observations expose limitations in a simple model describing exit point dynamics which is based only on the force balance on a particle of water at the sand surface and neglects subsurface pressures. A new modified form of the model is shown to significantly improve the model-data comparison through a parameterization of the effects of capillarity into the aquifer storage coefficient. The model enables sufficiently accurate predictions of the exit point to determine when the swash uprush propagates over a saturated or a partially saturated sand surface, potentially an important factor in the morphological evolution of the beach face. Observations of the shoreward propagation of the swash-induced pore pressure waves ahead of the runup limit shows that the magnitude of the pressure fluctuation decays exponentially and that there is a linear increase in time lags, behavior similar to that of tidally induced water table waves. The location of the exit point and the intermittency of wave runup events is also shown to be significant in terms of the shore-normal energy distribution. Seaward of the mean exit point location, peak energies are small because of the saturated sand surface within the seepage face acting as a ''rigid lid'' and limiting pressure fluctuations. Landward of the mean exit point the peak energies grow before decreasing landward of the maximum shoreline position.

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“…For example, seawater circulates through a coastal aquifer under the force of gravity (Li et al, 1999;Li and Jiao, 2003), from oceanic forces such as waves and tides (Taniguchi et al, 2002;Burnett et al, 2003), as a result of dispersive circulation along the freshwater-saltwater boundary within the aquifer (Kohout, 1960), and from changes in upland recharge (Michael et al, 2005).…”

Section: Groundwater Flow At the Coastmentioning

confidence: 99%