Complex drivers of reef-fronted beach change

Royal Hawaiian Beach in Waikīkī plays an essential role in Hawai‘i's tourism-based economy. To inform development of management policies, we conduct two years of weekly ground and aerial surveys (April 2018 to February 2020) to track change on this chronically eroding beach. We use multiple lin...

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Bibliographic Details
Published in:Marine geology 2022-04, Vol.446, p.106770, Article 106770
Main Authors: Mikkelsen, Anna B., Anderson, Tiffany R., Coats, Sloan, Fletcher, Charles H.
Format: Article
Language:English
Subjects:
Carbonate beach
Coastal processes
Environmental monitoring
Hawai‘i
Self-organizing maps
UAS surveys
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Summary:Royal Hawaiian Beach in Waikīkī plays an essential role in Hawai‘i's tourism-based economy. To inform development of management policies, we conduct two years of weekly ground and aerial surveys (April 2018 to February 2020) to track change on this chronically eroding beach. We use multiple linear regressions, Self-Organizing Maps (a form of cluster analysis), remotely sensed nearshore sand fields, hydrodynamic modelling, and monitoring of key physical processes to identify the principal drivers of beach change. Our results show 12 months of subaerial accretion (+2400 ± 59 m3) followed by 10 months of erosion (−3090 ± 51 m3) for a net loss of 690 ± 51 m3, and document that interannual variations in beach width and volume overprint seasonal patterns. Notably, a seasonal signal is recorded in the topographic structure of the beach. We test the relationship of beach volume and width to variations in wind, water level, wave energy flux generated from southern hemisphere swell, and wave energy flux from locally generated trade-wind waves. We identify three beach segments and three nearshore sand fields that form a sand-sharing, source-sink network, yet operate quasi-independently. Our analysis reveals that individual beach segments and their adjacent sand fields experience coherent (simultaneous) gains and losses of sand, suggesting that alongshore sediment exchange is dominant over cross-shore exchange. The main drivers of beach change are variations in water level and wave energy flux. Beach volume and width both vary with nearshore sand cover, indicating that free exchange with nearshore sources is intrinsic to beach variability. Our results suggest that rising sea level and extreme El Niño-Southern Oscillation events will contribute to Royal Hawaiian Beach destabilization, which may amplify erosional events and increase the cost of future beach maintenance. •Two years of weekly beach observations identify environmental drivers of change.•Seasonal beach change is overprinted by interannual processes of erosion/accretion.•Cluster analysis reveals that beach topography is organized by season.•Sediment exchange is dominated by alongshore, not cross-shore patterns.•Nearshore and intertidal sediments respond coherently to wave forcing.
ISSN:0025-3227
1872-6151
DOI:10.1016/j.margeo.2022.106770