The structure and organisation of integral marine benthic communities in relation to sieve mesh size

Somerfield, PJ; Dashfield, SL; Warwick, RM. 2017 The structure and organisation of integral marine benthic communities in relation to sieve mesh size. Journal of Experimental Marine Biology and Ecology. 10.1016/j.jembe.2017.08.007

[img] Text
Somerfield et al REVISED FINAL.docx - Submitted Version
Available under License Creative Commons Attribution No Derivatives.

Download (58kB)
Official URL:


Few studies consider meiofauna and macrofauna at the same time, even though both form parts of wider ecological networks, and fewer consider interactions between sample size, body size and spatial clustering. It has been suggested that the elements of the structure of the physical environment have fractal properties. If habitat complexity largely determines species diversity this leads to the prediction (for a single perfect fractal) that all organisms, regardless of size, will perceive the environment as equally complex and should have equivalent diversity and, as we move up the size spectrum, species composition should change in a regular and gradual fashion. This study examines the degree to which infaunal assemblage structure varies with mesh size, sample size and sample dispersion within two different areas of homogeneous intertidal sediment, a muddy sand and a coarse sand, in the Isles of Scilly, UK. In each area samples were extracted using a standard range of 5 mesh sizes (63, 125, 250, 500, 1000 um), with the sample areas and distances between samples scaled to the mesh size. All metazoans were identified to species level. Diversity and species composition did not show a gradual and even degree of change over the size range at either site. Instead, they showed a dramatic stepwise change between the 250 um and 500 um mesh size samples, being relatively constant in the <500 um and >500 um categories, with diversity higher in the former. Higher proportions of species in the <500 um categories showed evidence of spatial clustering than in the >500 um categories. This suggests a fractal structure within but not between the <500 um and >500 um body size categories, which apparently is not driven by differences in sediment structure. The biology of marine metazoan benthos does not scale continuously across the full range of taxa and body size as has been recently suggested, but may do so for individual taxa and restricted size ranges.

Item Type: Publication - Article
Additional Keywords: Body size; Fractal; Diversity; Sampling methods; Meiobenthos; Macrobenthos
Subjects: Conservation
Data and Information
Ecology and Environment
Divisions: Plymouth Marine Laboratory > Science Areas > Marine Ecology and Biodiversity
Depositing User: Dr Paul J Somerfield
Date made live: 10 Mar 2018 13:31
Last Modified: 10 Mar 2018 13:31

Actions (login required)

View Item View Item