Abstract
Elevation is a major driver of plant ecology and sediment dynamics in tidal wetlands, so accurate and precise spatial data are essential for assessing wetland vulnerability to sea-level rise and making forecasts. We performed survey-grade elevation and vegetation surveys of the Global Change Research Wetland, a brackish microtidal wetland in the Chesapeake Bay estuary, Maryland (USA), to both intercompare unbiased digital elevation model (DEM) creation techniques and to describe niche partitioning of several common tidal wetland plant species. We identified a tradeoff between scalability and performance in creating unbiased DEMs, with more data-intensive methods such as kriging performing better than 3 more scalable methods involving post-processing of light detection and ranging (LiDAR)-based DEMs. The LiDAR Elevation Correction with Normalized Difference Vegetation Index (LEAN) method provided a compromise between scalability and performance, although it underpredicted variability in elevation. In areas where native plants dominated, the sedge Schoenoplectus americanus occupied more frequently flooded areas (median: 0.22, 95% range: 0.09 to 0.31 m relative to North America Vertical Datum of 1988 [NAVD88]) and the grass Spartina patens, less frequently flooded (0.27, 0.1 to 0.35 m NAVD88). Non-native Phragmites australis dominated at lower elevations more than the native graminoids, but had a wide flooding tolerance, encompassing both their ranges (0.19, -0.05 to 0.36 m NAVD88). The native shrub Iva frutescens also dominated at lower elevations (0.20, 0.04 to 0.30 m NAVD88), despite being previously described as a high marsh species. These analyses not only provide valuable context for the temporally rich but spatially restricted data collected at a single well-studied site, but also provide broad insight into mapping techniques and species zonation.
Highlights
Saline and brackish marshes are vegetated ecosystems with specialized species that are adapted to live within the intertidal zone
Previous research has reported that P. australis invasion is typically limited to the high marsh and mid-marsh zones (Bertness et al 2002, Chambers et al 2003), but we found that P. australis is dominant in both the lower and higher elevation landward edge
We found that P. australis at Global Change Research Wetland (GCReW) dominates tidal wetlands beyond the physiological thresholds thought to limit its establishment and distribution
Summary
Saline and brackish marshes are vegetated ecosystems with specialized species that are adapted to live within the intertidal zone. Small relative elevation changes can affect phenomena such as vegetation zonation along gradients as much as a few centimeters (Castillo et al 2000) Information to parameterize these models comes from plants grown under controlled conditions at varying tidal elevations, so-called marsh organ experiments (Kirwan & Guntenspergen 2015, Langley et al 2013, Mozdzer et al 2016), as well as high resolution GPS surveys of elevation and biomass (Schile et al 2014) or plant presence and absence (Thorne et al 2018)
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