Abstract

AbstractCoral reefs are widely recognized for providing a natural breakwater effect that modulates erosion and flooding hazards on low‐lying sedimentary reef islands. Increased water depth across reef platforms due sea‐level rise (SLR) can compromise this breakwater effect and enhance island exposure to these hazards, but reef accretion in response to SLR may positively contribute to island resilience. Morphodynamic studies suggest that reef islands can adjust to SLR by maintaining freeboard (island crest elevation above still water level) through overwash deposition and island accretion, but the impact of different future reef accretion trajectories on the morphological response of islands remains unknown. Here we show, using a process‐based morphodynamic model, that, although reef growth significantly affects wave transformation processes and island morphology, it does not lead to decreased coastal flooding and island inundation. According to the model, reef islands evolve during SLR by attuning their elevation to the maximum wave runup and islands fronted by a growing reef platform attain lower elevations than those without reef growth, but have similar overwash regimes. The mean overwash discharge Qover across the island crest plays a key role in the ability of islands to keep up with SLR and maintain freeboard, with a Qover value of O (10 l m−1 s−1) separating island construction from destruction. Islands, therefore, can grow vertically to keep up with SLR via flooding and overwash if specific forcing and sediment supply conditions are met, offering hope for uninhabited and sparely populated islands. However, this physical island response will negatively impact infrastructure and assets on developed islands.

Highlights

  • Coral reef islands are wave-built accumulations of carbonate sediment deposited on sub-horizontal reef platforms with a reef edge that slopes steeply to deeper water

  • The island crest accretes in all simulations, but the amount of freeboard reduces throughout the simulation, especially for the sand island and for the fastest rate of sea-level rise (SLR)

  • A process-based numerical model was used to simulate the morphological response of gravel and sand coral reef islands to SLR and investigate the role of future reef growth on island response

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Summary

Introduction

Coral reef islands are wave-built accumulations of carbonate sediment deposited on sub-horizontal reef platforms with a reef edge that slopes steeply to deeper water. They tend to have a surface area O (0.1–1 km2) with their long axis oriented parallel to the prevailing wave direction, and they can be densely vegetated or developed with infrastructure. These pessimistic outlooks are based on both the reef platform and the island being geologically inert structures, and disregard two important processes that may positively contribute to island resilience to SLR

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