Accretion, retreat and transgression of coastal wetlands experiencing sea-level rise
journal contribution
posted on 2023-03-31, 05:48authored byA Breda, PM Saco, SG Sandi, N Saintilan, G Riccardi, JF Rodríguez
Abstract. The vulnerability of coastal wetlands to future sea-level
rise (SLR) has been extensively studied in recent years, and models of
coastal wetland evolution have been developed to assess and quantify the
expected impacts. Coastal wetlands respond to SLR by vertical accretion and
landward migration. Wetlands accrete due to their capacity to trap sediments
and to incorporate dead leaves, branches, stems and roots into the soil, and they migrate driven by the preferred inundation conditions in terms of
salinity and oxygen availability. Accretion and migration strongly interact, and they both depend on water flow and sediment distribution within the
wetland, so wetlands under the same external flow and sediment forcing but
with different configurations will respond differently to SLR. Analyses of
wetland response to SLR that do not incorporate realistic consideration of
flow and sediment distribution, like the bathtub approach, are likely to
result in poor estimates of wetland resilience. Here, we investigate how
accretion and migration processes affect wetland response to SLR using a
computational framework that includes all relevant hydrodynamic and sediment
transport mechanisms that affect vegetation and landscape dynamics, and it
is efficient enough computationally to allow the simulation of long time
periods. Our framework incorporates two vegetation species, mangrove and
saltmarsh, and accounts for the effects of natural and manmade features like
inner channels, embankments and flow constrictions due to culverts. We apply
our model to simplified domains that represent four different settings found
in coastal wetlands, including a case of a tidal flat free from obstructions
or drainage features and three other cases incorporating an inner channel,
an embankment with a culvert, and a combination of inner channel, embankment
and culvert. We use conditions typical of south-eastern Australia in terms of vegetation, tidal range and sediment load, but we also analyse situations
with 3 times the sediment load to assess the potential of biophysical feedbacks to produce increased accretion rates. We find that all wetland
settings are unable to cope with SLR and disappear by the end of the
century, even for the case of increased sediment load. Wetlands with good
drainage that improves tidal flushing are more resilient than wetlands with
obstacles that result in tidal attenuation and can delay wetland submergence by 20 years. Results from a bathtub model reveal systematic
overprediction of wetland resilience to SLR: by the end of the century, half
of the wetland survives with a typical sediment load, while the entire
wetland survives with increased sediment load.