Seagrass propagules dispersal: hydrodynamics

A small seedling of the seagrass Posidonia oceanica in a container filled with water

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Journal Papers

Pereda L, Infantes E, Orfila A, Tomas F, Terrados J

Marine Ecology Progress Series, 593: 47-59.

Publication year: 2018

Dispersal of seagrass propagules: interaction between hydrodynamics and substratum type

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ABSTRACT

Waves and currents influence not only the spatial distribution of seagrass meadows but also the transport, establishment and survivorship of seagrass propagules and hence the success of seagrass recruitment from sexual reproduction. We quantified the dispersal of propagules of three seagrass species (Posidonia oceanica, Cymodocea nodosa and Zostera marina) over substrata of different complexities (sand, coarse gravel, and P. oceanica matte of different shoot abundances) under unidirectional flow in a hydraulic flume.

Threshold velocities indicate that Z. marina seeds start to move earlier over a flat sandy bottom (14 cm s^-1) than P. oceanica (20 cm s^-1) and C. nodosa (21 cm s^-1) seeds. Propagule trapping increased with bottom complexity, which was related to the flow reduction that each substratum generated and their boundary layer thickness. Trapping rates were higher in coarse gravel and in high dead shoot abundance matte, where flow was reduced more than 50 %.

Over sand, flow reduction was minimal and propagules were not trapped. Furthermore, notable differences between P. oceanica early life stages were observed, being seeds trapped first, followed by seedlings of increasing ages, which appears to be related with the reduction of the frontal area and higher settling velocity of the younger stages. Together these results provide important insights into the drivers of seagrass recruitment, which are of interest for restoration purposes and numerical modelling.

DOI: doi.org/10.3354/meps12518

Highlights

Waves and currents affect seagrass propagule dispersal and recruitment success.
Study quantified dispersal of propagules of 3 seagrass species over different substrata.
Threshold velocities showed Z. marina seeds moved earlier than P. oceanica and C. nodosa seeds.
Propagule trapping increased with bottom complexity, and P. oceanica early life stages had notable differences in trapping rates.

Hydraulic flume used in the laboratory to simulate hydrodynamic conditions. ADV: acoustic Doppler velocimeter

Posidonia oceanica early life stages: (a) fruit and seed (0 wk old), and seedlings at 3, 8 and 25 wk of age. Also shown are seeds of (b) Cymodocea nodosa and (c) Zostera marina

Relation between trapping of Posidonia oceanica seeds and seedlings and substratum complexity in a 20 cm s−1 flow. Three rhizome abundances were used (75, 150 and 300 dead shoots m−2, at heights of 1 and 4 cm). Matte com- plexity was calculated as the number of rhizomes m−2 × rhi- zome height (cm). For coarse gravel, complexity was calcu- lated as the number of gravel pieces m−2 × gravel height. Complexity assigned to sand was 0

Relation between trapping of Posidonia oceanica seeds and seedlings and substratum complexity in a 20 cm s⁻¹ flow. Three rhizome abundances were used (75, 150 and 300 dead shoots m⁻², at heights of 1 and 4 cm). Matte com- plexity was calculated as the number of rhizomes m⁻² × rhizome height (cm). For coarse gravel, complexity was calculated as the number of gravel pieces m⁻² × gravel height. Complexity assigned to sand was 0