Marine zooplankton play an important role in the transfer of CO2 from the
atmosphere/ocean system to deeper waters and the sediments. They also provide food for
much of the world's fish stocks and in some areas of the ocean depleted of nutrients they
sustain phytoplankton growth by recycling nutrients. They therefore have a profound
effect on the carbon cycle and upon life in the oceans. There is a perceived lack of
information about global distributions of zooplankton needed to validate ecosystems
dynamics models, and the traditional methods of survey are inadequate to provide this
information. There is a need to develop new technologies for the large scale survey of
zooplankton, which should provide data either suitable for quick and easy subsequent
processing, or better still, processed in real time.
New technologies for large scale zooplankton survey fall into three main categories:
acoustic, optical and video. No single method is capable of providing continuous real
time data at the level of detail required. A combination of two of the new technologies
(optical and video) has the potential to provide broad scale data on abundance, size and
species distributions of zooplankton routinely, reliably, rapidly and economically. Such a
combined method has been developed in this study. The optical plankton counter (OPC)
is a fairly well established instrument in marine and freshwater zooplankton survey. A
novel application of the benchtop version of this instrument (OPC-IL) for real time data
gathering at sea over ocean basin scales has been developed in this study. A new
automated video zooplankton analyser (ViZA) has been designed and developed to
operate together with the OPC-IL. The two devices are eventually to be deployed in
tandem on the Undulating Oceanographic Recorder (UOR) for large scale ocean survey
of zooplankton.
During the initial development of the system, the two devices are used in benchtop flow
through mode using the ship's uncontaminated sea water supply. The devices have been
deployed on four major oceanographic cruises in the North and South Atlantic, covering
almost 40,000 km. of transect. Used in benchtop mode, it has been shown that the OPC
can simply and reliably survey thousands of kilometres of ocean surface waters for
zooplankton abundance and size distribution in the size range 250|im. to 11.314 mm. in
real time. The ViZA system can add the dimension of shape to the OPC size data, and
provide supporting data on size distributions and abundance. Sampling rate in
oligotrophic waters, and image quality problems are two main limitations to current
ViZA performance which must be addressed, but where sufficient abundance exists and
good quality images are obtained, the initial version of the ViZA system is shown to be
able reliably to classify zooplankton to six major groups.
The four deployments have shown that data on zooplankton distributions on oceanic
scales can be obtained without the delays and prohibitive costs associated with sample
analysis for traditional sampling methods. The results of these deployments are
presented, together with an assessment of the performance of the system and proposals
for improvements to meet the requirements specified before a fiill in-situ system is
deployed.
Date of Award | 1997 |
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Original language | English |
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Awarding Institution | |
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THE DEVELOPMENT OF NOVEL TECHNIQUES FOR CHARACTERISATION OF MARINE ZOOPLANKTON OVER VERY LARGE SPATIAL SCALES
GALLIENNE, C. P. (Author). 1997
Student thesis: PhD