2022
DOI: 10.3389/fmars.2022.958573
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Undeveloped and developed phases in the centennial evolution of a barrier-marsh-lagoon system: The case of Long Beach Island, New Jersey

Abstract: Barrier islands and their associated backbarrier environments protect mainland population centers and infrastructure from storm impacts, support biodiversity, and provide long-term carbon storage, among other ecosystem services. Despite their socio-economic and ecological importance, the response of coupled barrier-marsh-lagoon environments to sea-level rise is poorly understood. Undeveloped barrier-marsh-lagoon systems typically respond to sea-level rise through the process of landward migration, driven by st… Show more

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Cited by 5 publications
(7 citation statements)
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“…Modeling of decade to century-scale evolution of human-occupied barriers is limited (McNamara & Werner, 2008a, 2008bMagliocca et al, 2011;Rogers et al, 2015;Miselis & Lorenzo-Trueba, 2017;Karanci et al, 2017;Tenebruso et al, 2022), in part because it is challenging, involving human and natural dynamics that interact across nested spatial scales, and change over time in response to shifts in climate and land use (Lazarus et al, 2016). To overcome this, previous studies have relied on simplified morphodynamic models to investigate generalized behavior.…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…Modeling of decade to century-scale evolution of human-occupied barriers is limited (McNamara & Werner, 2008a, 2008bMagliocca et al, 2011;Rogers et al, 2015;Miselis & Lorenzo-Trueba, 2017;Karanci et al, 2017;Tenebruso et al, 2022), in part because it is challenging, involving human and natural dynamics that interact across nested spatial scales, and change over time in response to shifts in climate and land use (Lazarus et al, 2016). To overcome this, previous studies have relied on simplified morphodynamic models to investigate generalized behavior.…”
Section: Introductionmentioning
confidence: 99%
“…Within these exploratory model frameworks (Murray, 2003;, shoreface and barrier geometries are represented by idealized (nodal) profiles, and cross-shore and alongshore processes are represented through the application of simplifying assumptions. This approach has enabled the identification of important human-natural couplings, such as emergent instabilities in barrier morphology arising from short-term hazard mitigation and policy decisions (McNamara & Werner, 2008a, 2008b; differential filtering of overwash deposition by residential and commercial development (Rogers et al, 2015); shifts in natural patterns of barrier evolution (Tenebruso et al, 2022) and increased vulnerability of developed barriers to drowning by SLR (Miselis & Lorenzo-Trueba, 2017) stemming from human interference in barrier-marsh couplings (reduced overwash delivery, lagoon dredging); and greater swings in barrier stability and more rapid barrier narrowing as a result of dune management strategies (Magliocca et al, 2011).…”
Section: Introductionmentioning
confidence: 99%
“…Within these exploratory model frameworks (Murray, 2003(Murray, , 2013, shoreface and barrier geometries are represented by idealized (nodal) profiles, and cross-shore and alongshore processes are represented through the application of simplifying assumptions. This approach has enabled the identification of important human-natural couplings, such as emergent instabilities in barrier morphology arising from short-term hazard mitigation and policy decisions (McNamara & Werner, 2008a, 2008b; differential filtering of overwash by residential and commercial development (Rogers et al, 2015); shifts in natural patterns of barrier evolution (Tenebruso et al, 2022) and increased vulnerability of developed barriers to drowning by SLR (Miselis & Lorenzo-Trueba, 2017) stemming from human interference in barrier-marsh couplings (reduced overwash delivery, lagoon dredging); and greater swings in barrier stability and more rapid barrier narrowing as a result of dune management strategies (Magliocca et al, 2011).…”
Section: Introductionmentioning
confidence: 99%
“…Modeling of decade to century‐scale evolution of human‐occupied barriers is limited (Karanci et al., 2018; Magliocca et al., 2011; McNamara & Werner, 2008a, 2008b; Miselis & Lorenzo‐Trueba, 2017; Rogers et al., 2015; Tenebruso et al., 2022), in part because it is challenging, involving human and natural dynamics that interact across nested spatial scales (Hoagland et al., 2023), and change over time in response to shifts in climate and land use (Lazarus et al., 2016). To overcome this, previous studies have relied on simplified morphodynamic models to investigate generalized behavior.…”
Section: Introductionmentioning
confidence: 99%
“…The latter overlaps with the concept of geomorphic capital, which is defined as sediment reserves that must be exhausted before frontal erosion of a barrier transitions to wholesale migration (Mariotti and Hein, 2022). Mesoscale barrier dynamics also include human interventions, which have impacted coastal barriers directly and indirectly for decades to hundreds of years through the manipulation of sediment input and partitioning across the entire shoreface-barrier-marsh-lagoon system (Abam, 1999;Elko et al, 2021;Hein et al, 2019;Rogers et al, 2015;Tenebruso et al, 2022;Williams et al, 2013), as well as through stabilization and destruction of barrier geomorphic boundaries, such as the backbarrier-marsh interface (Stutz and Pilkey, 2005;Tenebruso et al, 2022).…”
Section: Introductionmentioning
confidence: 99%