Erosion of Frozen Cliffs Due to Storm Surge on Beaufort Sea Coast

A simple model is developed to predict the overall horizontal retreat of a frozen cliff fronted by a beach due to a storm surge on the Beaufort Sea coast. In this thermal and mechanical erosion model, storm surge and wave action on the frozen cliff causes the convective heat transfer and melting of...

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Published in:Journal of coastal research 1999-01, Vol.15 (2), p.332-344
Main Authors: Kobayashi, N., J. C. Vidrine, R. B. Nairn, S. M. Soloman
Format: Article
Language:English
Subjects:
Beaches
Cliffs
Coasts
Earth sciences
Earth, ocean, space
Exact sciences and technology
Marine
Marine and continental quaternary
Melting
Sea water
Sediment transport
Sediments
Storm surges
Storms
Surficial geology
Waves
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container_end_page 344
container_issue 2
container_start_page 332
container_title Journal of coastal research
container_volume 15
creator Kobayashi, N.
J. C. Vidrine
R. B. Nairn
S. M. Soloman
description A simple model is developed to predict the overall horizontal retreat of a frozen cliff fronted by a beach due to a storm surge on the Beaufort Sea coast. In this thermal and mechanical erosion model, storm surge and wave action on the frozen cliff causes the convective heat transfer and melting of the ice-bonded cliff sediment, which supplies coarse sediment on the beach whereas fine sediment is assumed to be transported offshore. The volume balance for the unfrozen coarse sediment on the beach is used to predict the vertical beach erosion. When the frozen beach sediment is exposed to wave action, the beach erosion is controlled by the convective heat transfer and melting of the frozen beach sediment. The developed model is compared and calibrated using the observed cliff retreat due to a September, 1993 storm on the Canadian Beaufort Sea coast. The calibrated model is then used to assess the degree of importance of various factors that affect the thermal and mechanical erosion of the frozen cliff and beach. This assessment suggests that the accurate prediction of the cliff and beach erosion will require quantitative data on storm surge elevation and duration, cliff height, seawater temperature and salinity, sediment characteristics and wave conditions.
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source JSTOR Archival Journals
subjects Beaches
Cliffs
Coasts
Earth sciences
Earth, ocean, space
Exact sciences and technology
Marine
Marine and continental quaternary
Melting
Sea water
Sediment transport
Sediments
Storm surges
Storms
Surficial geology
Waves
title Erosion of Frozen Cliffs Due to Storm Surge on Beaufort Sea Coast
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