Phytoplankton physiology and primary productivity at basin scales were determined using
in situ data from fast repetition rate (FRR) fluorometry. Samples were collected along
the Atlantic Meridional Transect cruise 11 (AMTll, September-October 2000), between
50°N and 33°S in the Atlantic Ocean.
Because of the large-scale nature of the study, consistent knowledge about oceanographic
conditions and the phytoplankton community structure of each sampling station were
required. The province analysis was carried out by detecting the regional variations
of water mass characteristics in the upper 200 m layer. Temperature versus salinity
diagrams were plotted at each station and further analyses of nitrate and chlorophyll were
carried out for confirmation of the provinces. The structure of phytoplankton community
and its distribution were assessed by statistical analyses of the phytoplankton pigments
detected by high performance liquid chromatography. The phytoplankton physiology was
assessed with FRR fluorometry to retrieve the quantum yield of photochemistry (Fv/Fm),
the effective absorption cross-section (cpsII) and the turnover time of photosystem II
(TQA). Some assumptions and parameterisations allowed the determination of primary
productivity fractionated for prochlorophytes and eukaryotes from Fv/Fm and apsII-
The classification of the regional variation of water masses through temperature and
salinity relationships turned out to be a quick and simple analysis for the detection of
provinces, defining eight provinces along the transect. Phytoplankton were distributed
in three communities which were stratified along the transect. The limits between the
communities were at variable depths depending on the province. The shape of the vertical
profile of Fv/Fm and its pre-dawn to mid-day variation were also dependent on
the province. In the Equatorial upwelling region and at the depth of deep chlorophyll
maximum in the oligotrophic gyres, e.g. where nitrate was replete, values of Fv/Fm
were relatively low at both pre-dawn and mid-day stations. This persistent low value of
Fv/Fm at pre-dawn, e.g. after overnight darkness in nitrate replete conditions, leads to
the proposition of iron limitation. In the upper layer of the oligotrophic gyres, nocturnal
recovery of Fv/Fm was observed, indicating nitrate limitation rather than iron limitation.
In the light limited part of the water column (PB) varied proportionally and consistently
to the light intensity. Station analysis of PB showed photosaturation at low light levels
at which the radiocarbon method was insensitive. The FRRF method was more precise,
reflecting better the environmental conditions at the time of sampling than the results
of radiocarbon P-E experiments. The upper layer of Atlantic Ocean was photosaturated
due to the physiological impairment caused by either nitrate or iron limitation yet the
zone of photosaturated photosynthesis contributed more to the primary productivity of
the water column than the zone of light limited photosynthesis. The primary production
fractionated for prochlorophytes and eukaryotes, indicated that the former contributed to
more than half of the total production in the gyres.
FRR fluorometry has been demonstrated to be a promising option for primary productivity
studies, especially at basin scales, that allows 'continuous' measurement through the
water column. Exploiting the capability of this method is valuable for the understanding
of photosynthesis in the natural environment and more important than attempting to
reconcile it to the traditional method of radiocarbon incorporation.
Date of Award | 2003 |
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Original language | English |
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Awarding Institution | |
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Investigation of primary productivity along the Atlantic Meridional Transect (50°N to 33°S) through fast repetition rate fluorometry
Omachi, C. Y. (Author). 2003
Student thesis: PhD