Advances in the state-of-the-art in the quantitative ecology of the marine megabenthos
This study attempts to advance the quantitative ecology of the megabenthos by (i) adopting and developing the use of mass seabed photography, and by(ii) extending body-size-based ecosystem assessment to this group. The metabolic theory of ecology (MTE) builds from simple bio-energetic assumptions of...
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| Format: | Thesis |
| Language: | English |
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University of Southampton
2020
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| Online Access: | https://eprints.soton.ac.uk/444730/ https://eprints.soton.ac.uk/444730/1/Benoist_Noelie_PhD_thesis_Oct_2020.pdf |
| Summary: | This study attempts to advance the quantitative ecology of the megabenthos by (i) adopting and developing the use of mass seabed photography, and by(ii) extending body-size-based ecosystem assessment to this group. The metabolic theory of ecology (MTE) builds from simple bio-energetic assumptions of individual metabolism to make predictions about ecological processes from individual structure and functioning, to community and ecosystem dynamics. Under the ‘energetic equivalence rule’, or Damuth’s rule, the population density of living organisms is related to a -3/4 power of body mass, indicating equal resource acquisition across body-size classes. In the marine environment, meio- to macrobenthic assemblages have be usefully modelled as a notional single trophic level, suggesting energetic equivalence throughout the two fractions. That concept is tested here by extension to the megabenthos. The body-size structure of benthic assemblages was examined in four contrasting settings: two shelf-sea sites in the Celtic Sea (Greater Haig Fras marine conservation zone; Shelf-Sea Biogeochemistry area), and two deep sea sites (Porcupine Abyssal Plain sustained observatory, PAP-SO, northeast Atlantic; Clarion-Clipperton Zone, CCZ, northeast Pacific). Imagery data were collected using autonomous underwater vehicles, allowing consistent assessment of the megabenthos in the form of individual-based body-size spectral analyses, over landscape-scale areas encompassing multiple habitat types. For the well-known Celtic Shelf and PAP-SO assemblages, species specific length-weight relationships were used to derive individual biomass data. However, that was not possible for the poorly studied CCZ fauna, prompting the development of a generalised volumetric method for individual body-mass estimation. The MTE framework was used to investigate the effects of seafloor temperature and resource supply on the stocks and flows of mass and energy at these sites. The results of this study demonstrate the practical advantage of mass seabed ... |
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