Impacts of Coastal Infrastructure on Shoreline Response to Major Hurricanes in Southwest Louisiana

Cadigan, Jack A.; Bekkaye, Jasmine H.; Jafari, Navid H.; Zhu, Ling; Booth, Ashley R.; Chen, Qin; Raubenheimer, Britt; Harris, Brian D.; O'Connor, C.; Lane, Robert R.; Kemp, G. Paul; Day, John; Day, John W.; Ulloa, Hanssel Omar

doi:10.3389/fbuil.2022.885215

Cited by 6 publications

(10 citation statements)

References 27 publications

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“…The prototype LLC LiDAR consists of six major components: [1] Slamtec RPLiDAR A1M8 (R5) 360 • laser range scanner (USD 110); [2] Raspberry Pi 3B+ single board computer and 32 GB microSD card (~USD 40, in 2020); [3] Anker PowerCore+ 26,800 mAh PD USB battery pack (USD 140); [4] 3D printed (PLA), custom-designed mounting bracket (<USD 2); [5] Polycase enclosure (Part # WC-41) (USD 45); [6] Polycase aluminum baseplate (Part # WX-42) (USD 13). The hole pattern aligned with the 3D printed mounting bracket was manually drilled into the aluminum baseplate.…”

Section: Design and Operationmentioning

confidence: 99%

“…The destructiveness of tropical cyclones has been increasing over the past several decades, which may be attributed to longer lived, more energetic storms [1], and to a higher frequency of occurrence and magnitude of rapid intensification [2,3]. This increase in destructiveness, coupled with rising coastal populations [4] and infrastructure demands [5], contribute to large economic cost of these storms [6].…”

Section: Introductionmentioning

confidence: 99%

“…Fully standalone, self-contained systems with low infrastructure requirements are necessary for rapid-deployability when predictions of location(s) that may experience the most significant impact(s) are uncertain or widespread. Low cost is also a high priority, due to potential loss of equipment during storm impact [3,20].…”

Section: Introductionmentioning

confidence: 99%

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Beach Profile, Water Level, and Wave Runup Measurements Using a Standalone Line-Scanning, Low-Cost (LLC) LiDAR System

O’Connor

Mieras

2022

Remote Sensing

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A prototype rapidly deployable, Line-scanning, Low-Cost (LLC) LiDAR system (USD 400 per unit; 2020) was developed to measure coastal hydro-morphodynamic processes. A pilot field study was conducted at the U.S. Army Corps of Engineers, Field Research Facility (FRF) in Duck, North Carolina, USA to evaluate the efficacy of the LLC LiDAR in measuring beach morphology, wave runup, and free-surface elevations against proven approaches. A prototype LLC LiDAR collected continuous cross-shore line scans for 25 min of every half hour, at ~7 revolutions/s and ~1.3° angular resolution, at two locations (one day at each location), spanning 12 m (i) on the backshore berm (35 scans; Series B) and (ii) in the swash/inner surf zone (28 scans; Series C). LLC LiDAR time-averaged beach profiles and wave runup estimates were compared with the same quantities derived from the continuously sampling terrestrial LiDAR scanner installed atop the dune at the FRF (DUNE LiDAR). The average root-mean-square difference (RMSD) between 17 (6) time-averaged LLC and DUNE LiDAR beach profiles was 0.045 m (0.031 m) with a standard deviation of 0.004 m (0.002 m) during Series B (Series C). Small-scale (cm) swash zone bed level changes were resolved over 5-min increments with the LLC LiDAR. The RMSD between LLC- and DUNE LiDAR-derived wave runup excursions over two 25-min segments was 0.542 m (cross-shore) and 0.039 m (elevation) during the rising tide and 0.366 m (cross-shore) and 0.032 m (elevation) during the falling tide. Between 72–79% of the LLC LiDAR wave runup data were more accurate than the RMSD values, thereby demonstrating the LLC LiDAR is an effective, low-cost instrument for measuring wave runup and morphodynamic processes. Co-located water levels were measured with a continuously sampling (16 Hz) RBRsolo3 D|wave16 pressure logger during Series C. LLC LiDAR free-surface elevations at the nadir during one high tide (4.5 h) compared well with pressure-derived free-surface elevations (RMSD = 0.024 m, R2 = 0.85).

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Section: Design and Operationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Beach Profile, Water Level, and Wave Runup Measurements Using a Standalone Line-Scanning, Low-Cost (LLC) LiDAR System

O’Connor

Mieras

2022

Remote Sensing

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“…The salt marsh resistance to these external factors is linked to sediment dynamics, with a major emphasis placed on vertical accretion and relative sea‐level rise that links to interior marsh ponding (Cadigan et al., 2022; Day et al, 1998; FitzGerald et al, 2008; Kirwan et al, 2016; Pethick, 1993; Priestas et al, 2015; Temmerman & Kirwan, 2015; Temmerman et al, 2005). However, salt marshes are also inherently weak and vulnerable to shoreline retreat (i.e., marsh edge erosion) caused by waves from hurricanes and storms (Barras et al, 1994; Cadigan et al, 2022; Day et al, 2007; Jadhav et al, 2013). Analysis by Penland et al (2000) specifically shows that approximately 25% of the wetland loss in the Mississippi River Delta Plain from 1932 to 1990 was attributed to erosion due to wind‐driven waves.…”

Section: Introductionmentioning

confidence: 99%

“…Marsh edge erosion occurs when wind waves attack marsh boundaries (e.g., Bendoni et al, 2014; Leonardi et al., 2016; Leonardi & Fagherazzi, 2014; Mariotti & Fagherazzi, 2013; Marani et al, 2011; Schwimmer & Pizzuto, 2000; Wiberg et al., 2020). The factors influencing marsh edge erosion consist of severity of wind‐generated waves (Fagherazzi et al, 2006; Mariotti & Fagherazzi, 2010), vegetation root strength (D'Alpaos et al, 2007; Koppel et al, 2005; Paul & Amos, 2011), anthropogenic land use and land change (Gedan et al, 2009), and geotechnical properties of cohesive mudflat sediments (Bloemendaal et al, 2021; Cadigan et al, 2022; Feagin et al, 2009; Howes et al, 2010; Jafari et al, 2019). Existing models in Table 1 for predicting marsh edge evolution focus primarily on edge retreat rates as a function of wave energy, while accounting for other controlling factors into empirical constants, though recent work suggests that many salt marshes show a very weak or non‐existent relationship between wave power and erosion rates (Bloemendaal et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Near‐continuous monitoring of a coastal salt marsh margin: Implications for predicting marsh edge erosion

Cadigan

Jafari

Wang

et al. 2023

Earth Surf Processes Landf

Self Cite

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Mechanisms that control marsh edge erosion include wind‐generated waves, vegetation productivity, land use and land change, and geotechnical properties of sediments. However, existing models for predicting marsh edge evolution focus primarily on edge retreat rates as a function of wave energy while accounting for other controlling factors as empirical constants. This simplification arises from a lack of high‐frequency monitoring of marsh evolutions. In particular, marsh erosion is timescale dependent, and conducting field observations on short temporal and spatial scales could elucidate the progression of erosion, which may improve marsh erosion predictive models. This study developed and validated a near‐continuous camera and erosion pin monitoring system to document marsh edge erosion at a high frequency (i.e., daily) in Terrebonne Bay, Louisiana. This was supplemented with daily wave power to explore the relationships between daily erosion and wave power. Long‐term average erosion rates derived from satellite and aerial imagery from 1989 through 2019 compare similarly to rates derived from longer‐term site visits (i.e., monthly) at approximately 2.2 m/yr. High‐magnitude erosion events (>20 cm/day) are driven by a buildup in wave energy over a 7‐day time period coupled with a strong 1‐day wave event, indicating a gradual reduction in marsh edge resistance with continued wave attack. Long‐term erosion monitoring methods, including monthly field visits, provide results that align well with previously reported relationships between wave power and erosion. High‐frequency measurements, however, illustrate that the previously published trends smooth over the large‐magnitude short‐term erosion events, potentially obscuring the physical processes of marsh edge erosion. For example, satellite and aerial imagery provide a long period of record, but they may underestimate the average annual erosion rate in the region, the effect of which may become exasperated over the varying temporal scales considered in coastal planning efforts across the USA and worldwide.

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A review of issues related to formation, deterioration and restoration of the Chenier Plain, Mississippi River Delta, LA - Combining nature based and engineered approaches

Norman¹,

Hunter²,

Day³

et al. 2022

Nature-Based Solutions

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Impacts of Coastal Infrastructure on Shoreline Response to Major Hurricanes in Southwest Louisiana

Cited by 6 publications

References 27 publications

Beach Profile, Water Level, and Wave Runup Measurements Using a Standalone Line-Scanning, Low-Cost (LLC) LiDAR System

Beach Profile, Water Level, and Wave Runup Measurements Using a Standalone Line-Scanning, Low-Cost (LLC) LiDAR System

Near‐continuous monitoring of a coastal salt marsh margin: Implications for predicting marsh edge erosion

A review of issues related to formation, deterioration and restoration of the Chenier Plain, Mississippi River Delta, LA - Combining nature based and engineered approaches

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