Disturbance of sedimentary processes in tidal salt marshes invaded by exotic vegetation

In situ moorings were conducted at salt marsh and bare flat to reveal the environmental disturbance of sedimentary processes in the intertidal flat. Spartina alterniflora (Spartina), an invasive species, grew up to 156 cm in the Ganghwa tidal flat from June to November 2019. This rapid growth has resulted in the dense salt marsh, which complicated hydrodynamics and associated sediment processes. Stems and leaves could effectively trap fine-grained sediments (17.24-20.42 mu m) at the bed, increasing the differences in bed elevation between the two sites to up to 5.11 cm. The cohesive sediments accumulated in Spartina communities were resuspended differently by stem-scale turbulence generated from the disturbance of stems and leaves, depending on wind forcing and vegetation conditions. The vegetated sediments, under low wind speeds (<4 m s(-1)), were hardly resuspended in the water column, compared to those in the bare flat, resulting in sedimentation. Under high wind speeds (>6 m s(-1)), stem-scale turbulence was sufficiently strengthened to surpass the sedimentation of suspended sediments; thus, it resuspended additional bed sediments without a loss of the trapped sediment, unlike in the bare flat. The flocculation of suspended sediments in Spartina communities was mainly controlled by stem-scale turbulence. The flocs were confined to a size of 40 mu m (settling velocity: 0.17mms(-1)) and developed an approaching spherical shape. After the cut-off of Spartina, a favorable condition for the flocs to grow by 57 mu m (settling velocity: 0.23mms(-1)) was established with decrease in stem-scale turbulence. These larger flocs were able to develop into a ramified spherical structure. Despite diminishment of stem-scale turbulence, the disturbed sediments were outflowed, resulting in an abrupt decrease in bed elevation (0.12 cm day(-1)). The results suggest that the sediment accumulated in Spartina communities remained erodible due to frequent disturbanceswithout sufficient consolidation. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

The study revealed that the rapid growth of Spartina on the tidal flat led to the complexity of the salt marsh zone, affecting hydrodynamics and sediment processes. The stems and leaves could effectively trap fine-grained sediments, resulting in significant differences in bed elevation between the two sites. Flocculation of suspended sediments in Spartina communities was mainly controlled by stem-scale turbulence.