The majority of the earth's surface (-71%) is covered by the aquatic
environment where 97% of that is the oceanic regime. Almost every part of the
aquatic regime is dominated by microscopic plants called phytoplankton. Being at the
bottom of the food chain, these ecological drivers influence the earth's climate system
as well as the biodiversity trends of other organisms such as zooplankton, fish, sea
birds and marine mammals.
The aim of this research was to understand the ecology of phytoplankton and
assess which environmental, physical, biological, and spatiotemporal factors influence
their distribution and abundance. Using this information a knowledge-based expert
system discriminated phytoplankton functional types. The ecological knowledge was
derived from the Continuous Plankton Recorder (CPR) survey, whereas information
regarding the physical regime was acquired from satellite remote sensing. The data
matrix was analysed using Generalised Additive Models (GAMs) and Artificial
Neural Networks (ANNs).
The significant relationships developed by the synergistic use of CPR measure
of phytoplankton biomass and satellite chlorophyll a (Chl-a), allowed the production
of a >50 years Chl-a dataset in the Northeast Atlantic and North Sea. It was found that
the documented mid-80s regime shift corresponded to a 60% increase in Chl-a since
1948; a result of an 80% increase in Chl-a during winter alongside a smaller summer
increase.
GAMs indicated that the combined effects of high solar radiation, shallow
mixed layer depth and increased temperatures explained more than 89% of the
coccolithophore variation. The June 1998 bloom, which was associated with high
light intensity, unusually high sea-surface temperature (SST) and a very shallow
mixed layer, was found to be one of the most extensive ( -1 million kmĀ² )
blooms ever
recorded. There was a pronounced SST shift in the mid-1990s with a peak in 1998,
suggesting that exceptionally large blooms are caused by pronounced environmental
conditions and the variability of the physical environment strongly affects the spatial
extent of these blooms.
Diatom abundance in the epipelagic zone of the Northern North Atlantic was
mainly driven by SST. The ANNs indicated that higher SSTs could lead to a rapid
decrease in diatom abundance; increased SST can stratify the water column for longer
preventing nutrients from being available. Therefore, further increases may be
devastating to diatoms but may benefit smaller plankton such as coccolithophores
and/or dinoflagellates.
Finally, the knowledge gained though the developed methodological
approaches was used to identify/discriminate phytoplankton functional groups
(diatoms, dinoflagellates, coccolithophores and silicoflagellates) with an accuracy of
greater than 70%. The most important information for phytoplankton functional group
discrimination was spatiotemporal information, and for the physical environment was
SST. Future research aimed at the identification of functional groups from remotely
sensed data should include fundamental information on the physical environment as
well as spatiotemporal information and not just based on bio-optical measurements.
Further development, potential applications and future research are discussed.
Date of Award | 2006 |
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Original language | English |
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Awarding Institution | |
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UNDERSTANDING OF THE VARIABILITY OF PHYTOPLANKTON ECOSYSTEM FUNCTION PROPERTIES: A SYNERGISTIC USE OF REMOTE SENSING AND IN SITU DATA
RAITSOS-EXARCHOPOULOS, D. (Author). 2006
Student thesis: PhD