Implications for the resilience of modern coastal systems derived from mesoscale barrier dynamics at Fire Island, New York

IF 2.8 2区地球科学 Q2 GEOGRAPHY, PHYSICAL

Earth Surface Dynamics Pub Date : 2024-03-14 DOI:10.5194/esurf-12-449-2024

Daniel J. Ciarletta, Jennifer L. Miselis, Julie C. Bernier, Arnell S. Forde

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Abstract

Abstract. Understanding the response of coastal barriers to future changes in rates of sea level rise, sediment availability, and storm intensity/frequency is essential for coastal planning, including socioeconomic and ecological management. Identifying drivers of past changes in barrier morphology, as well as barrier sensitivity to these forces, is necessary to accomplish this. Using remote sensing, field, and laboratory analyses, we reconstruct the mesoscale (decades–centuries) evolution of central Fire Island, a portion of a 50 km barrier island fronting Long Island, New York, USA. We find that the configuration of the modern beach and foredune at Fire Island is radically different from the system's relict morphostratigraphy. Central Fire Island is comprised of at least three formerly inlet-divided rotational barriers with distinct subaerial beach and dune–ridge systems that were active prior to the mid-19th century. Varying morphologic states reflected in the relict barriers (e.g., progradational and transgressive) contrast with the modern barrier, which is dominated by a tall and nearly continuous foredune and is relatively static, except for erosion and drowning of its fringing marsh. We suggest that this state shift indicates a transition from a regime dominated by inlet-mediated gradients in alongshore sediment availability to one where human impacts exerted greater influence on island evolution from the late 19th century onward. The retention of some geomorphic capital in Fire Island's relict subaerial features combined with its static nature renders the barrier increasingly susceptible to narrowing and passive submergence. This may lead to an abrupt geomorphic state shift in the future, a veiled vulnerability that may also exist in other stabilized barriers.

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从纽约火岛的中尺度屏障动力学得出的现代沿岸系统复原力的含义

摘要了解沿岸障碍物对未来海平面上升率、沉积物可利用性和风暴强度/频率变化的响应，对于沿岸规划，包括社会经济和生态管理，都是至关重要的。要做到这一点，就必须找出过去障碍物形态变化的驱动因素以及障碍物对这些力的敏感性。利用遥感、现场和实验室分析，我们重建了火岛中部中尺度（数十年至数百年）的演变过程，火岛是美国纽约长岛前沿 50 公里屏障岛的一部分。我们发现，火岛现代海滩和前沙丘的构造与该系统的遗迹形态地层学截然不同。火岛中部至少由三个以前由入海口分割的旋转屏障组成，这些屏障具有不同的次生海滩和沙丘-沙脊系统，在 19 世纪中期以前非常活跃。遗迹屏障中反映出的不同形态状态（如前倾和后退）与现代屏障形成鲜明对比，现代屏障以高大且近乎连续的前沙丘为主，除边缘沼泽受到侵蚀和淹没外，相对静止。我们认为，这种状态的转变表明，从 19 世纪晚期开始，沿岸沉积物可用性的梯度由入海口介导的制度主导，过渡到人类影响对岛屿演化产生更大影响的制度主导。火岛残存的次地貌保留了一些地貌资本，再加上其静态性质，使得屏障越来越容易变窄和被动淹没。这可能会导致未来地貌状态的突然转变，这种隐蔽的脆弱性也可能存在于其他稳定的屏障中。

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来源期刊

Earth Surface Dynamics GEOGRAPHY, PHYSICALGEOSCIENCES, MULTIDISCI-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

5.40

自引率

5.90%

发文量

审稿时长

20 weeks

期刊介绍： Earth Surface Dynamics (ESurf) is an international scientific journal dedicated to the publication and discussion of high-quality research on the physical, chemical, and biological processes shaping Earth''s surface and their interactions on all scales.