Groundwater-Table Responses to Wave Run-up: An Experimental Study from Western Australia

Groundwater-table responses to wave run-up were observed on a natural sandy beach at South City Beach, Western Australia. The run-up spectrum was dominated by a broad band of swell energy. In contrast the groundwater spectrum was dominated by low-frequency energy. Thus the beachface and sediment mat...

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Bibliographic Details
Published in:Journal of coastal research 1991, Vol.7 (3), p.623-634
Main Authors: HEGGE, B. J, MASSELINK, G
Format: Article
Language:English
Subjects:
Beaches
Brackish
Earth sciences
Earth, ocean, space
Exact sciences and technology
Freshwater
Geology
Groundwater
Hydraulics
Hydrogeology
Hydrology. Hydrogeology
Marine
Outcrops
Series convergence
Splashing
Water pressure
Water tables
Waves
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Summary:Groundwater-table responses to wave run-up were observed on a natural sandy beach at South City Beach, Western Australia. The run-up spectrum was dominated by a broad band of swell energy. In contrast the groundwater spectrum was dominated by low-frequency energy. Thus the beachface and sediment matrix effectively filter input swash oscillations as they are transmitted through to the groundwater-table. The filtering appears to be that of a band-pass filter in which oscillations with a frequency of 0.013 Hz (77 s) are less attenuated than either longer or shorter period fluctuations. Despite intense filtering, groundwater-table oscillations at incident swell frequencies were still detected. These oscillations were closely related to swash motions on the beachface. Low-amplitude run-up did not induce a detectable response in the groundwater-table, and the groundwater-level continued to decline. Swashes with moderate run-up resulted in the transmission of a pressure force, via the saturated sands, which induced a temporary stabilizing of the falling groundwater-level. Swashes that extended beyond the mean groundwater-table level caused the groundwater-table to rise. The water-table rise and rate of rise were directly related to the amplitude of swash run-up. The groundwater-table rise was caused by swash water infiltration and in part by the reversed Wieringermeer effect. A groundwater-table response asymmetry was detected whereby the groundwater-level rises more rapidly than it falls.
ISSN:0749-0208
1551-5036