Field and Numerical Investigations of Wave Effects on Groundwater Flow and Salt Transport in a Sandy Beach

Coastal dynamic forces, such as waves and tides, altogether drive groundwater circulation and salt transport in the intertidal zone. However, few numerical studies have ever considered the combined effects of waves and tides. In this study, the fluctuations of wave height are integrated with tidal l...

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Bibliographic Details
Published in:Water resources research 2022-11, Vol.58 (11), p.n/a
Main Authors: Yu, Shengchao, Wang, Chaoyue, Li, Hailong, Zhang, Xiaolang, Wang, Xuejing, Qu, Wenjing
Format: Article
Language:English
Subjects:
Beaches
coastal beach
Coastal dynamics
Efflux
Flow-density-speed relationships
Freshwater
Groundwater
Groundwater discharge
Groundwater flow
Inland water environment
Intertidal environment
Intertidal zone
iterative algorithm
Iterative algorithms
Iterative methods
Mathematical models
Salinity
Salt advection
Salts
Sea level
Sea level measurements
Simulation
Surf zone
Tidal effects
tidal level
Tides
Wave effects
Wave height
wave setup
Waves
Wind speed
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Summary:Coastal dynamic forces, such as waves and tides, altogether drive groundwater circulation and salt transport in the intertidal zone. However, few numerical studies have ever considered the combined effects of waves and tides. In this study, the fluctuations of wave height are integrated with tidal level together using an iterative least squares fitting method, in which the wave height can be acquired from measured sea level in the surf zone, and this fitted wave height is further verified by wind speed. Groundwater flow and salt transport were then simulated using the MARUN code to evaluate the impacts after considering wave effect. The simulated equivalent freshwater head and salinity of the model with wave effect presented less difference with the measured data compared with the simulated results of the model without wave effect. After incorporating the wave effect in a model, submarine groundwater discharge (SGD) was increased, among which recirculated SGD grew more rapidly than the fresh, leading to the proportion of the fresh SGD accounting for a small proportion (1.1%). The water influx and efflux rates increased greatly especially during the period of high wave height. Most of the influx occurred in the intertidal zone, while a considerable amount of efflux occurred in the subtidal zone. The iterative algorithm to separate the wave height from the mixed field data can be employed to identify and quantify the respective effects of tides and the combined effects of waves and tides on the density‐dependent beach groundwater flow. Key Points A new iterative algorithm was proposed to quantify tidal level and wave height using hourly measured surf zone sea level data Beach groundwater flow and salinity distribution were numerically reproduced using wave height and setup as boundary conditions Waves may significantly change groundwater flow and salinity distribution in a beach aquifer
ISSN:0043-1397
1944-7973
DOI:10.1029/2022WR032077