Mangroves as Coastal Protection for Restoring Low-Energy Waterfront Property
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Department of Ocean Engineering and Marine Sciences, College of Engineering and Science, Florida Institute of Technology, 150 W. University Blvd., Melbourne, FL 32901, USA
2
U.S. Army Engineer Research and Development Center, 3909 Halls Ferry Rd., Vicksburg, MS 39180, USA
*
Author to whom correspondence should be addressed.
J. Mar. Sci. Eng. 2024, 12(3), 470; https://doi.org/10.3390/jmse12030470
Submission received: 7 February 2024
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Revised: 29 February 2024
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Accepted: 5 March 2024
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Published: 9 March 2024
(This article belongs to the Special Issue Coastal Ecological Restoration: Techniques and Novel Approaches to Living Shorelines and Oyster Reef Construction)
Abstract
:Mangroves offer vital ecological advantages including air and water filtration, coastal and estuarine habitat provision, sediment stabilization, and wave energy dissipation. Their intricate root systems play a key role in safeguarding shorelines from tsunamis and erosive storms by dissipating wave energy. Moreover, mangroves shield against boat wakes and wind-waves, thus naturally bolstering shoreline defense. Wave dissipation is a function of forest width, tree diameter, and forest density. Restoration efforts of juvenile mangroves in Florida’s Indian River Lagoon (IRL) aim to reduce wave energy in areas vulnerable to erosion. Physical model testing of wave dissipation through mangroves is limited due to the complexity in representing the mangrove structure, where prop roots are non-uniform in both diameter and location. Previous studies have quantified wave-dissipating effects through the use of scaled and parameterized mangrove structures. This study measures the dissipation effects of live mangroves in a wave flume, forced by conditions representative of the IRL. These measurements are used to validate a parameterized dowel model. Error between wave attenuation factors for the live mangrove and dowel system was on average 2.5%. Validation of the modularized dowel system allowed for further parameterized testing to understand forest structure effects, such as sediment stabilization and wave attenuation. Maximum wave attenuation achieved in this study was 27–35% corresponding to a 40–60% reduction in wave energy depending on the configuration of the system. The wave reduction resulted in a 50–70% decrease in sediment erosion from the berm. The dowel tests indicate a target minimum thickness for mangrove root systems of 0.6 m for shoreline stabilization and restoration in the IRL.
1. Introduction
Mangroves play a critical role along estuarine shorelines in tropical and subtropical regions by stabilizing shorelines, creating natural habitats, absorbing and filtering nutrients, and sequestering carbon [1]. Benefits of mangrove vegetation steeply contrast with “hardened” or armored shoreline stabilization methods, such as seawalls and revetments, which abruptly disrupt natural sediment transport resulting in scour and downdrift erosion [2] and provide little to no ecological benefits. Erosion mitigation with hardened structures may decrease shoreline retreat but neglect to provide similar ecological benefits associated with natural and nature-based shorelines. A shift towards natural and nature-based solutions, such as oyster reef breakwaters, marsh grasses, and mangroves, harness the benefits of natural shoreline stabilization without inducing negative effects associated with hardened armoring [3,4]. Efforts along the Florida coast have attempted to reestablish mangrove forests as natural erosion mitigation.
Mangrove forests are notable for mitigating long-wave tsunami effects [5,6,7], particularly along Vietnam coastlines where forest widths extend upwards of 24 km [8]. However, forest widths within Florida’s estuaries along residential properties are typically much less than 33 m and encounter short-period waves (<15 s). Wind-wave periods in the Indian River Lagoon (IRL) on Florida’s East coast are limited by the shallow water depth, short fetch, and the restricted nature of the estuary. Frictional drag created by mangrove roots on short-period waves results in turbulent, multi-directional flow that dissipates wave energy [9,10,11,12,13]. Under high water conditions, such as storm surge, leaves may become submerged, resulting in even greater wave dissipation due to the increase in submerged surface area and associated drag friction [12,14,15]. Mangrove attenuation properties are relative to water levels, wave and current energies, and plant geometry, consisting of aerial and prop roots, branches, and leaves. Plant features create drag in the water column and are a function of species, density, forest width, and age [14]. While these plant features are important, herein we focus on submerged aerial or ‘prop’ roots. Forest width and forest density increase as mangrove forests mature, further reducing forest porosity and increasing wave attenuation properties [11,16,17]. Field studies provide ranges of mangrove characteristics, and Bryant et al. [18] provides thorough guidance for mangrove field measurement methods. Aside from shoreline stabilization and wave attenuation, ecological and economic benefits from mangroves include increased habitat for marine life, filtering nutrients, and creating commercial and recreational fishing areas.
Dissipation effects of mangrove roots have been relatively well studied under long period tsunami waves; however, few laboratory studies have addressed the effects of mangrove roots under short-period waves, such as wind waves and boat wake. Physical mangrove modeling is difficult due to the complexity of the plants. Multiple studies have attempted to recreate the mangrove forest structure. Tuyen and Hung [19] used Sonneratia mangrove branches in a wave flume to simulate a mangrove forest under scaled storm surge at mean water levels in Vietnam. Husrin et al. [20] validated a parameterized model under current flow by using a scaled replication of a mangrove root structure. Hashim et al. [14] built scale models of mangroves using wire to compare the effects of mangrove forest configuration and density under short-period waves. Hu et al. [21] studied wave dissipation effects of a parameterized model with the addition of a current, resulting in an empirical relationship between the Reynolds number and drag coefficient. Bryant et al. [18] evaluated dissipation effects of near-prototype scale Rhizophora mangle in a large wave flume. The aforementioned studies relied on field measurements to parameterize mangrove models.
Florida has three mangrove species: red mangrove (Rhizophora mangle), white mangrove (Luguncularia racemose), and black mangrove (Avicennia germinans). Among the three mangrove species in Florida, red mangroves are found at or below shorelines, are typically partially submerged and will be the focus herein. The location of mangroves is dependent on climate, water and soil salinity, tidal fluctuation, and substrate makeup [22]. Additionally, plant biomass productivity correlates to salinity, nutrient, and coastal energy in estuarine regions [23,24]. Florida estuaries and rivers provide near-ideal conditions for mangrove growth, particularly for shoreline restoration efforts.
Local efforts within the Indian River Lagoon (IRL) along central East coast Florida have attempted to restore natural mangrove habitats for shoreline stabilization, and economic and ecological benefits. The IRL is a shallow and narrow restricted estuarine system [25] along the east coast of Florida, approximately 200 km long (N–S), 2–4 km wide (W–E), and 0.3 to 3.6 m in depth [26,27]. The narrow restriction of the lagoon impedes tidal flushing, resulting in high concentrations of nutrients. Local red mangroves help to filter these nutrients, naturally cleaning the lagoon. Based on analysis of satellite imagery from 2006–2011, approximately 32 km2 of mangroves existed between St. Lucie Inlet and Satellite Beach in the IRL [28]. However, mangroves are often removed during coastal development to reduce obstruction of views, resulting in a large loss of ecosystem benefits. Removal is typically due to federal regulations that regulate crown trimming if the plants were to remain. Removal can result in erosion due to unstable shoreline sediments [29].
This study investigates wave attenuation, wave energy dissipation, and sediment transport effects of mangroves using a validated, parameterized physical model. Validation of wave energy dissipation using a parameterized dowel system was completed using live mangroves under identical forcing conditions in a wave flume. Additional testing was completed using the dowel system to quantify the effects of forest width, density, and cross-shore sediment transport.
2. Materials and Methods
Three phases of physical modeling were completed in the Florida Institute of Technology (FIT) wave tank. A modular dowel mangrove design (MDMD) was used for idealized testing. The first phase consisted of placing live mangroves in the wave flume to validate hydrodynamic responses around the MDMD. The second phase consisted of evaluating forest parameter effects on wave dissipation using the MDMD. The third phase consisted of evaluating cross-shore sediment transport within the MDMD. Low energy wave and water level conditions and sediment profiles were selected to be representative of those found in the IRL.
2.1. Tank Setup and Data Analysis
The FIT wave tank is 9.1 m long, 0.56 m wide, and 0.91 m deep; with an effective length of 6.7 m with either a piston or flap paddle. A wave generator is attached to an adjustable stroke length to modify the wave height. Testing was completed using the piston wave paddle for 1.5, 2, and 3 s periods and the flap wave paddle for 1, 1.2, and 1.5 s periods. The piston paddle generates larger amplitude waves than the flap paddle; however, steepness limited breaking occurred at the validation water levels for the piston paddle, so these results are not discussed herein. Therefore, the flap paddle was used for forest width and frontal area coverage testing to create non-breaking waves to evaluate dissipation solely due to interactions between the wave and mangroves.
Wave heights were measured in the wave flume on the up-tank (seaward) and down-tank (leeward) side of the mangrove and MDMD systems using Sonic Wave Sensor XB from Ocean Sensor Systems, Inc. (Coral Springs, FL, USA) with a tolerance of 0.01 cm. Wave heights on the seaward side were used to confirm the desired incident wave was achieved; however, no wave reflection analysis was completed. Wave data were filtered using Hampel and 3rd order Butterworth filters to reduce noise, then a wave-by-wave analysis was completed to calculate significant wave heights. Wave reduction coefficients were computed by comparing the transmitted wave height with mangroves to the transmitted wave height without mangroves.
Shoreline stabilization was evaluated using cross-shore sediment heights. Sediment height changes were recorded at measurement stations located in 0.3 m increments. Stabilization was assessed by comparing the equilibrium sediment profile with the initial profile. Horizontal berm retreat was estimated using images of the cross-sectional profile. Total erosion and deposition on the leeward and seaward side were also estimated from these measurements.
2.2. Modular Dowel Mangrove Design Validation
The MDMD was validated using live mangroves in the wave tank to accurately simulate wave dissipation through a mangrove forest. A wave reduction factor (WRF) was used to compare dissipative effects and was defined as the nondimensionalized ratio between the wave height on the leeward with the system in place and the wave height on the leeward without the system in place (“control”). This method accounts for any wave transformation that occurs between the two wave gauges due to wave-bottom interactions.
Live mangroves were placed in the wave tank to simulate a mangrove forest, Figure 1a. The plants were 3 to 10 years old and on loan from the Marine Resource Council (MRC) in Melbourne, FL. Mature plants contained a main stem and prop roots and juvenile plants taller than 0.3 m were used to simulate additional roots to achieve the desired plant density. Larger plants were placed in the center of the tank and smaller plants and propagules filled in spaces to achieve a front area coverage of 50%. A level 0.25 m sediment profile was placed on the bottom of the tank to cover the mangrove containers. The profile sloped seaward to the bottom of the tank to replicate the IRL’s bathymetric slope [30] and a dissipative stone revetment was placed at the end of the tank in the lee of the simulated forest to limit wave reflection from the flume wall. The total forest length perpendicular to the shoreline (i.e., cross-shore span) was 1.45 m and the root density at the sediment level was approximately 200 mangrove prop roots per square meter, or one prop root every 50 square centimeters.
The MDMD is a system used to simulate mangrove roots that consists of a plywood frame with uniformly drilled holes and attached to the top of the wave tank, Figure 1b. The frame holds 1.3 cm diameter wooden dowels up to a 0.61 m cross-shore length and 0.56 m along shore width (i.e., across tank). Multiple frames can be concatenated to simulate a greater forest cross-shore length. These frames are designed to provide up to 100% frontal area coverage.
Columns and rows were defined on the frame, Figure 2. Columns were defined as the sets of holes on the same cross-shore plane and are 1.3 cm wide. Rows were defined as sets of holes on the along-shore plane. The frame has 16–17 holes per column and 20–21 holes per row. “Bands” of forest are approximately 10 cm wide and defined as the number of rows required to achieve the desired front area coverage at the desired dowel density, either 5 or 6 consecutive rows. Each wooden dowel is approximately 1.2 m long. Front area coverage is associated with the percentage of projected area to total area of the cross-tank plane that is occupied by one band of dowels. Holes in the frame are offset to achieve 100% coverage. Volume ratios are used to compare volume of dowels VD to total band volume VT. At a constant area over depth, a 100% front area coverage corresponds to a volume ratio of 0.1, which is similar to volume ratios of wild red mangroves [16].
To simulate the live mangrove tests, the lower ends of the dowels were buried into the sediment, which had the same bathymetric profile as the live mangrove configuration. Dowels were placed in the frames based on output from a random number generator in MATLAB. This method was used to create an effective forest cross-shore length of 1.45 m, with an average density of one dowel per 50 square centimeters, and 50% front area coverage; creating the same conditions measured in the live mangrove testing.
2.3. Modular Dowel Mangrove Design (MDMD) Testing
Further testing was completed with the MDMD to evaluate the effects of forest width and front area coverage. Front area coverage values of 100%, 75%, and 50% were achieved using either a 5-row band or combined 5- + 6-row (11-row) grouping of bands. The effects of 1 to 3 sets of bands were tested. A constant 12.7 cm sediment layer was used to stabilize the bottom of the dowels, which would otherwise move under wave forcing. Waves were generated with the flap paddle at periods of 1 and 1.5 s for a non-breaking wave. The tank was filled to 25.4 cm, resulting in a water depth of 12.7 cm over the sediment for the validation of the MDMD and to evaluate effects of forest width and front area coverage.
2.4. Sediment Transport Experiments
Sediment samples were collected from Riverview Park in Melbourne, FL at three locations along a cross-shore profile: just above, at, and just below the mean high-water line. Additionally, three sediment samples were collected from the existing sediment in the FIT wave tank. Samples were analyzed based on the American Society for Testing and Materials (ASTM) grain size distribution standards [31,32]. Sediment fall velocity was computed based on guidance from the Coastal Engineering Manual (CEM) [33]. Average Dn50 for the field samples was 0.40 mm and average Dn50 for wave tank samples was 0.28 mm. Sediment fall velocity of the average field sample was 0.20 m/s and average wave tank sample was 0.17 m/s.
Red mangrove prop roots and aerial root diameter measurements were taken at Riverview Park in Melbourne, FL. Seven measurements were collected in total from two mangrove trees using a Husky Digital Caliper which has an accuracy of 0.003 cm, Figure 3. Diameters ranged from 0.9 to 2.8 cm with an average of 1.7 cm and standard deviation of 0.76. The diameter difference between the measured roots and the 1.3 cm dowels on the MDMD was found to be not significant, though having dowels of varying size would more accurately mimic nature.
A cross-shore sediment profile was constructed to replicate the foreshore slope of a representative shoreline in the IRL. An A-frame with mesh covering was placed at the end of the tank to reduce incident wave reflections. A horizontal 0.61 m long berm was constructed away from the A-frame at a 0.45 m height then sloped at a 1:4 slope towards the bottom of the tank over a length of 1.8 m. Measurements were recorded at stations marked 0.3 m apart, Figure 4.
Effects of MDMD on sediment transport were evaluated at three water levels centered around a measured mean high water (MHW) at Riverview Park in Indialantic, FL, a location of a previous oyster restoration project in the IRL [30]. The annual high water (AHW) is a peak water level that only occurs once a year, typically between October to November in the IRL. The MHW and mean sea level (MSL) are average water levels over the national epoch. In the IRL, shorelines mostly experience MHW and MSL conditions. The representative MHW in the wave tank worked out to 0.30 m above the bottom of the tank. Based on this value, the corresponding depths used in the experiment for MSL, MHW, and AHW are 0.22 m, 0.30 m, and 0.38 m, respectively, see Figure 4.
Average expected wave heights were computed from fetch- and depth-limited wave equations, found in the Shore Protection Manual [34]. Typical fetch lengths in the IRL range between 2 and 4 km [27]. Water depths in the IRL range from 0.0 to 3.6 m, with the depth near the shoreline being near 0.3 m, and typically ranging from 0.9 to 1.8 m elsewhere [35]. Herein, a fetch length of 4 km and depth of 1.8 m was used for conservatism. A wind speed of 4.8 m/s or 10.8 mph was used, corresponding to measurements from the 2013–2018 National Data Buoy Center (NDBC) at Sebastian Inlet station SIPF1. Resulting fetch-limited wave heights were 0.15 m with a period of 1.5 s.
The test duration was 3 h and 23 min, which was determined to be the required time to achieve sediment equilibrium through previous testing. Sediment transport testing was conducted with zero MDMD bands as a control, and 1-, 2-, 4-, and 6-bands of dowels. Sediment profiles were reshaped between tests. Three replicates were measured for the MHW and one replicate for each of the MSL and AHW. Sediment height changes were recorded at a 0.3 m spacing for each test; total erosion and deposition between 0–1.2 m on the leeside of the MDMD and 1.2–3.0 m on the seaward side of the MDMD were estimated. Shoreline stabilization was measured based on the change in the vertical profile during the testing compared to the initial profile, measured at 0.3 m increments. Horizontal berm retreat was estimated using images of the cross-sectional profile.
3. Results and Discussion
The results of the MDMD validation against live mangroves are presented, followed by the results of the wave dissipation and then shoreline stabilization testing using the MDMD system.
3.1. Modular Dowel Mangrove Design (MDMD) Validation
Wave reduction factors were computed for each trial. These factors were compared between the live mangroves and MDMD validation configurations resulting in a percent difference, Table 1. The average percent difference between the live mangroves and the MDMD validation was 2.5%. This validation provides the hydrodynamic uncertainty associated with parameterizing mangrove forests with dowels, which was previously not comprehensively confirmed using live mangroves in a controlled setting.
In general, the wave reduction factors ranged from 0.60–0.80 for both the live mangroves and the dowels with the flap paddle. These reduction factors are similar to those found in the literature [18]; however, direct comparison with previous studies is limited due to the differences in variable ranges in experimental setups. Differences in the wave reduction factor between the live mangroves and dowels ranged between 0.7–5.7%. Previous reports [36] reported a 3.2% average difference; however, that difference included results from the waves generated by the piston-type paddle. The waves generated by the piston paddle for these tests were highly nonlinear. These nonlinearities included shallow water breaking across the length of the tank and resulted in high levels of turbulence before the wave impacted the MDMD. To narrow the scope of this work only the results produced by the waves generated with the flap style wavemaker were considered. In general, differences between the live mangroves and the dowels are relatively small and are within the expected uncertainty range associated with physical wave modeling.
3.2. Modular Dowel Mangrove Design (MDMD) Testing
After validation against live mangroves, the MDMD was reconfigured to evaluate the dissipative effects of band thickness, number of bands, and front area coverage. An example of the model setup highlights the MDMD and the location of the wave gauges in the wave tank, Figure 1b. The flap paddle was used herein to ensure non-breaking waves. The effect of band thickness (5- or 11-row) and additional bands (1, 2, or 3) at 100%, 75%, and 50% front area coverage are presented in Figure 5 and Figure 6.
Energy loss was greater for the 11-row band than for 5-row bands, for identical front area coverage, number of dowels, and wave conditions, Figure 5. Dowel placement was denser for the 5-row bands than the 11-row bands to achieve the same front area coverage; recall that front area coverage is a function of the area of the plane perpendicular to wave propagation and not forest width. The longer waves, 1.5 s, were impacted more by the widening of the bands from 5 to 11 rows. The greater breadth of contact allowed for more of the wave to be interacting with the structure and more time over which the wave was impacting the simulated root structures. These results suggest that root density plays a less important role in wave energy dissipation than cross-shore forest width. The increase in wave energy dissipation for the longer forest width is likely due to the increase in turbulence development over time in the system. In general, the wave attenuation decreased more between the 50% and 75% front area coverage than it did between the 75% and 100% front area coverage. This suggests there is an optimal front area coverage where the wave energy is most effectively reduced per a minimum front area coverage; however, in all cases the 100% front area coverage attenuated more energy than the 75% and 50%. Results also affirm that shorter period waves are more easily attenuated than longer period waves.
The effects of the number of bands, each with the same front area coverage (50, 75, and 100%), for both the 5- and 11-band widths and 1 s and 1.5 s periods on wave reduction are presented in Figure 6. Wave attenuation increased as front area coverage increased, due to the increased friction in the simulated forest. At the 1 s period, the mangroves were generally better able to attenuate wave energy, likely due to the increase in wave steepness. The longer waves, 1.5 s, were impacted more by the widening of the bands from additional 5 to 11 rows while keeping the front area coverage constant. The greater breadth of contact allowed for more time over which the wave was impacting the simulated root structures. Waves will feel the wider root structure more significantly. Since the 1 s wave is attenuated more efficiently by the shorter width than the 1.5 s wave, the difference for the 1 s wave will not be as pronounced as that seen in the 1.5 s wave. As expected, as the band number increased, the wave attenuation properties increased. This reduction in wave energy is due to the increase in friction with the addition of simulated mangrove roots; however, even at the greatest band number and front area coverage tested, a 100% wave attenuation is difficult to achieve in a narrow estuarine system due to the restricted available cross-shore area for mangrove growth. The natural permeability of the root system will allow wave propagation shoreward of the mangrove forest. Greater wave attenuation can be achieved over time as forest front area coverage and overall cross shore width increases. This decrease in wave energy in the cross-shore will promote shoreline accretion, while the mangrove roots will reduce erosion during large storm events by stabilizing the sediment.
Wave attenuation properties were also dependent on wave steepness and wave period, where the 1 s wave with a greater steepness was attenuated more effectively than the 1.5 s wave. Not only do shorter period waves carry less energy and have less momentum than longer period waves, but also as the wave steepness increases, a wave is more prone to breaking upon impacting the root structure at any given time. Although not presently studied, mangroves may be able to provide further shoreline protection during large storm and hurricane force waves due to the added frictional surface area of canopy leaves that the incident wave may impact under increased water levels.
3.3. Sediment Transport
Cross-shore sediment transport was evaluated using the MDMD using the tank setup depicted in Figure 4. Vertical changes compared to initial cross-shore profile were measured at 0.3 m (1 ft) increments and the horizontal berm retreat was evaluated. Average equilibrium profiles from the three replicate tests for MHW are shown in Figure 7 for 1- and 2-band tests (a) and the 2-, 4- and 6-band tests (b).
In the MHW testing, the cross-sectional profiles showed a net offshore transport for all tests; however, the greatest erosion at station zero occurred for the control when zero bands were present. For the control and test with 1 and, sediment was lost outside of the measurement area towards the seaward side. Additionally, due to the 0.3 m measurement resolution, sediment changes are likely not fully characterized within the profile. As bands increased, erosion between stations 0 and 3 typically decreased. Tests with 1 band showed the formation of an offshore berm on the seaward side of the MDMD. Tests with 2 and 4 bands were nearly identical and showed the formation of a small berm. Variations between replicates were low for the MHW testing, with a maximum standard deviation between individual station replicates of 0.067 and an average standard deviation for all stations of 0.018. Relatively large variations between replicates for zero and 1-band tests are likely due to drastic profile changes related to higher wave energy between stations 0 and 4. Other variations between replicates are associated with sand waves, where measurements may be measured at either a ridge or runnel whose locations change between replicates.
The equilibrium profile heights at MSL, Figure 8, were similar to those at MHW but were less pronounced. Only one testing replicate was completed because of the low variation seen at MHW testing and the 4-band testing was not presented because of no significant difference between four and 6-band results, as shown by the very low standard deviations above for the MHW testing. There was no berm retreat for any test with the MDMD and minimal retreat for the control, further discussed below. Overall net sediment transport from the lee of the MDMD was lower than that of the MHW, likely due to the shallower water depth resulting in decreased wave energy acting on the profile and breaking waves acting lower on the profile.
Equilibrium profiles for AHW are shown in Figure 9. For this case, erosion extended back to the A-Frame. Vertical decrease at the A-frame, station zero, is more pronounced than at MSL and MHW. Net cross-shore transport shows erosion at 0 m, signs of a berm formation between 1.22 and 2.13 m, and sediment loss outside of the measurement area for nearly all scenarios. A possible wave node or antinode may have influenced the creation of the berm between 1.22 and 2.13 m; however, hydrodynamic measurements were not resolved to evaluate this in the present study. In general, as the number of bands increased, the net offshore transport decreased.
The average sediment transport at MHW between stations is shown in Figure 10 where negative values correspond to erosion and positive values correspond to accretion. The control had the most net erosion on the leeward side of the MDMD. Tests with 1 band had the greatest accretion on the seaward side of the MDMD. Tests with 2, 4, and 6 bands had similar net transport. The standard deviation of sediment transport between bands was computed for each station, with a maximum standard deviation of 0.013 at 0 and 0.3 m distance; however, the other measurement locations had standard deviations between 0.001 and 0.007. The larger variation between sediment transport is likely due to erosion occurring for the control and 1-band cases at 0 and 0.3 m, but no erosion at these locations for the other band scenarios. Without including variations at 0 and 0.3 m, the variation between the cross-sectional sediment transport was insignificant, with an absolute maximum change in sediment level between these bands of 0.008 m and maximum standard deviation of 0.05. This demonstrates the significant benefit for the shoreline of an adequately wide mangrove forest for erosion mitigation and shoreline protection. Additionally, as it was eroded from the shoreline, sediment was transported through and deposited in front of the simulated root system (as would be expected in nature). This accretion in front of the simulated mangrove roots was seen in all cases as a bar or berm depending on the water level and number of bands. By accumulating eroded material into a bar-like structure in front of the mangroves, the onset of wave breaking is pushed upstream of the mangrove roots, enhancing the mangroves’ ability to dissipate wave energy.
Horizontal berm retreat was evaluated at each water level and band configuration. Results of linear meters of berm loss are shown in Table 2. The greatest level of complete berm retreat to the A-frame was at AHW for all band configurations; although for the 6-band scenario, this maximum retreat was smaller than the retreat measured at MHW for the control and 1-band case. Berm retreat decreased with decreasing water levels, where MSL had no berm retreat except for the control. Increasing the number of dowels generally decreased erosion and increased shoreline stabilization.
In this study, a simulated forest width of 2 bands, which is equal to an effective mangrove forest width of 0.2 m, was demonstrated to be the minimum width for initializing shoreline stabilization at MHW and MSL. However, most shoreline damage does not occur during typical conditions. The most erosion occurred during the AHW, a seasonal high-water level associated with coastal ocean dynamics. The 6-band results at the AHW, equal to an effective mangrove forest width of 0.6 m, would likely be the most realistic shore protection to prevent erosion during extreme events in the IRL. Only 6 bands were evaluated within this study, so further investigation is required to determine the benefits of additional forest width for extreme events.
4. Conclusions
As the Coastal Engineering community moves toward hybrid designs for coastal restoration and protection, emphasis has been placed on quantifying engineering benefits of natural and nature-based features and green designs. This study developed a method to quantify mangrove forest effectiveness for shoreline protection in relatively low wave environments. The simple modularized dowel method represents live mangroves within 2.5% accuracy on average in wave channel physical modeling. The MDMD allows for further investigation of mangrove forest parameters associated with aerial and prop roots and their influence on shoreline protection. Additional investigation is required to quantify the effects of other mangrove features, such as submerged leaves, with a parameterized model. Using the MDMD, this study concludes that restoration efforts in low energy environments, such as the IRL, should attempt to plant out or construct a mangrove forest with a design thickness of 0.6 m in the cross-shore at a density of 1 prop root per 50 sq cm. Under these design conditions, the maximum wave attenuation achieved in this study was 27–35% corresponding to a 40–60% reduction in wave energy depending on the wave period. The wave reduction resulted in a 50–70% decrease in sediment erosion depending on the mean water level. This design is expected to provide an initial level of protection from yearly erosive events, and it is expected that wave attenuation within the forest will increase as the plants continue to grow. This MDMD system could be used in future studies to examine, under worst case scenario of water levels and wave energy, the limit of mangrove cross-shore width needed to prevent sediment motion. Managers could then estimate how long it will take for the restoration plantings to reach that width based on mangrove growth rates. This information would help improve restoration guidelines and additional research is required to holistically quantify these effects.
Author Contributions
Conceptualization, R.J.W.; methodology, R.J.W. and A.L.S.; software, R.J.W.; validation, R.J.W. and A.L.S.; formal analysis, R.J.W. and A.L.S.; investigation, R.J.W. and A.L.S.; resources, R.J.W.; data curation, R.J.W.; writing—original draft preparation, A.L.S. and R.J.W.; writing—review and editing, A.L.S. and R.J.W.; visualization, A.L.S. and R.J.W.; supervision, R.J.W.; project administration, R.J.W.; funding acquisition, R.J.W. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the State of Florida DEO_Grant #HL037 and the Indian River Lagoon Research Institute at Florida Institute of Technology.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
The raw data supporting the conclusions of this article will be made available by the authors on request.
Acknowledgments
The authors would like to acknowledge the participation of State of Florida DEO_Grant #HL037 collaborators, and the students who assisted in the lab. We would also like to thank the Marine Resource Council, MRC, for their support generously lending live red mangrove plants for us to test in the wave tank.
Conflicts of Interest
The authors declare no conflicts of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.
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Figure 1.
Wave tank setup for MDMD validation. (a) Live mangroves in the wave tank with water. Stone revetment at the left end of the tank to simulate representative shoreline and reduce reflected waves. Plant containers are buried in the sediment. (b) MDMD system setup in the tank with wave gauges installed seaward and leeward from the system. Sediment height and offshore slope are kept constant between the cases. Location of the wave gauges is kept constant between the simulations.
Figure 1.
Wave tank setup for MDMD validation. (a) Live mangroves in the wave tank with water. Stone revetment at the left end of the tank to simulate representative shoreline and reduce reflected waves. Plant containers are buried in the sediment. (b) MDMD system setup in the tank with wave gauges installed seaward and leeward from the system. Sediment height and offshore slope are kept constant between the cases. Location of the wave gauges is kept constant between the simulations.
Figure 2.
MDMD plan design. Tank edges are at the top and bottom of the image; incident waves propagate from the right. One column is highlighted horizontally in the image. Bands are defined vertically in the image and alternate between 5 and 6 rows.
Figure 2.
MDMD plan design. Tank edges are at the top and bottom of the image; incident waves propagate from the right. One column is highlighted horizontally in the image. Bands are defined vertically in the image and alternate between 5 and 6 rows.
Figure 3.
Field measurement of Red Mangrove aerial root.
Figure 4.
Initial cross-sectional profile for sediment stabilization tests without MDMD. The location of the MDMD testing is overlayed with the cross-shore extent of the 1-band (yellow), 2-band (cyan), 4-band (green), and 6-band (purple) set -up included as dashed vertical lines in the gridded (white lines) overlay. The three dashed/dotted blue lines represent AHW (long dash), MHW (short dash), and MSL (dotted). The orange line represents the initial profile. The points indicated in the orange line are the sediment measurement locations, also indicated by the vertical taped markings on the tank picture. These measurement locations are spaced every 0.3 m.
Figure 4.
Initial cross-sectional profile for sediment stabilization tests without MDMD. The location of the MDMD testing is overlayed with the cross-shore extent of the 1-band (yellow), 2-band (cyan), 4-band (green), and 6-band (purple) set -up included as dashed vertical lines in the gridded (white lines) overlay. The three dashed/dotted blue lines represent AHW (long dash), MHW (short dash), and MSL (dotted). The orange line represents the initial profile. The points indicated in the orange line are the sediment measurement locations, also indicated by the vertical taped markings on the tank picture. These measurement locations are spaced every 0.3 m.
Figure 5.
The wave reduction effects due to front area coverage percent are shown for both the 5- and 11-band forest width cases. Both the 5-row bands and the 11-row bands have the same number of rods for each respective case. The Density (%) on the x-axis refers to the front area coverage. Red lines and markers are for 1.5 s wave periods and blue lines and markers are for 1 s wave periods for the 1-band (circle), 2-band (triangle), and 5-band (square) tests.
Figure 5.
The wave reduction effects due to front area coverage percent are shown for both the 5- and 11-band forest width cases. Both the 5-row bands and the 11-row bands have the same number of rods for each respective case. The Density (%) on the x-axis refers to the front area coverage. Red lines and markers are for 1.5 s wave periods and blue lines and markers are for 1 s wave periods for the 1-band (circle), 2-band (triangle), and 5-band (square) tests.
Figure 6.
Plots for each of the three tested front area coverage amounts (100%, 75%, and 50%), comparing the wave reduction as a function of the number of bands (representing forest thickness) for the 5- and 11-row band groupings. In each front area coverage case, every band has the same coverage percentage. Red lines and markers are for 1.5 s wave periods and blue lines and markers are for 1 s wave periods. Star markers are 5-row bands and square markers are 11-row bands.
Figure 6.
Plots for each of the three tested front area coverage amounts (100%, 75%, and 50%), comparing the wave reduction as a function of the number of bands (representing forest thickness) for the 5- and 11-row band groupings. In each front area coverage case, every band has the same coverage percentage. Red lines and markers are for 1.5 s wave periods and blue lines and markers are for 1 s wave periods. Star markers are 5-row bands and square markers are 11-row bands.
Figure 7.
Average equilibrium profiles from MHW testing for the (a) 1- and 2-band tests and (b) the 2-, 4-, and 6-band tests. Control is in grey for both figures, with the initial profile in orange.
Figure 7.
Average equilibrium profiles from MHW testing for the (a) 1- and 2-band tests and (b) the 2-, 4-, and 6-band tests. Control is in grey for both figures, with the initial profile in orange.
Figure 8.
Average equilibrium profiles from MSL testing.
Figure 9.
Average equilibrium profiles from AHW testing.
Figure 10.
Average sediment transport at MHW at each station.
Table 1.
The results and error difference for the live mangroves and the dowel system are shown for periods ranging from 1 s to 1.5 s, using a flap paddle.
Table 1.
The results and error difference for the live mangroves and the dowel system are shown for periods ranging from 1 s to 1.5 s, using a flap paddle.
| Period (s) | Paddle Type | Wave Reduction Factor | % Difference | |
|---|---|---|---|---|
| Live Mangroves | Dowels | |||
| 1 | Flap | 0.62 | 0.66 | 5.7% |
| 1.2 | Flap | 0.72 | 0.77 | 0.7% |
| 1.5 | Flap | 0.76 | 0.78 | 2.7% |
| Average | 2.5% | |||
Table 2.
Measured berm retreat during the test cases.
| Test Case | Berm Retreat (m) | ||||
|---|---|---|---|---|---|
| Control | 1-Band | 2-Band | 4-Band | 6-Band | |
| AHW | 0.61 | 0.61 | 0.61 | n/a | 0.30 |
| MHW | 0.53 | 0.46 | 0.10 | 0.14 | 0.17 |
| MSL | 0.10 | 0.00 | 0.00 | n/a | 0.00 |
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Weaver, R.J.; Stehno, A.L. Mangroves as Coastal Protection for Restoring Low-Energy Waterfront Property. J. Mar. Sci. Eng. 2024, 12, 470. https://doi.org/10.3390/jmse12030470
AMA Style
Weaver RJ, Stehno AL. Mangroves as Coastal Protection for Restoring Low-Energy Waterfront Property. Journal of Marine Science and Engineering. 2024; 12(3):470. https://doi.org/10.3390/jmse12030470
Chicago/Turabian StyleWeaver, Robert J., and Abigail L. Stehno. 2024. "Mangroves as Coastal Protection for Restoring Low-Energy Waterfront Property" Journal of Marine Science and Engineering 12, no. 3: 470. https://doi.org/10.3390/jmse12030470
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