Modelling the effect of vertical mixing on bottle incubations for determining in situ phytoplankton dynamics. I. Growth rates

Ross, Oliver N.; Geider, Richard J.; Berdalet, Elisa; Artigas, Mireia L.; Piera, Jaume

doi:10.3354/meps09193

Cited by 27 publications

(42 citation statements)

References 54 publications

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“…1 shows a comparison of the 2 productivities for a range of environmental conditions. In agreement with our findings regarding the growth rates (Ross et al 2011), the error in the productivity scales with both τ m and ξ SML (Fig. 1a-d (c,d), are for a shallow and deep surface mising layer (SML) respectively and the parameters are chosen such that the optical depth ξ SML = 5.4 and the mixing time scale τ m = 100 h are the same for both set-ups.…”

Section: Figuresupporting

confidence: 70%

“…For each depth bin, we therefore calculate the carbon production per unit volume during the fixeddepth incubations, P incub (z), and compare it with the production in the freely mixing SML, P mixed (z). The difference is displayed as the percent over-or underestimation (1) or depth integrated as Table 2 in Ross et al (2011) and Table 1 in Ross & Geider (2009 ). As we are not interested in absolute magnitudes but only in differences between the mixed and fixed-depth scenarios, we display those units as 'arbitrary' in the plots.…”

Section: Methodsmentioning

confidence: 99%

“…The biological model used for the comparison is based on the RG I model in Ross & Geider (2009) and the full set of equations and associated parameters is contained in Ross et al (2011;their Appendix 1). To quantify the errors we focus on how primary production is affected by the fixed-depth incubation procedure.…”

Section: Methodsmentioning

confidence: 99%

“…We present possible explanations for how previous authors could have arrived at contradictory results and discuss whether they might be artefacts related to the particular sampling protocol used. We discuss the errors associated with chlorophyll-based incubation methods for determining in situ phytoplankton growth rates in Ross et al (2011; Mar Ecol Prog Ser 435:13-31). …”

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confidence: 99%

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Modelling the effect of vertical mixing on bottle incubations for determining in situ phytoplankton dynamics. II. Primary production

Ross¹,

Geider²,

Piera³

2011

Mar. Ecol. Prog. Ser.

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C) during the incubation period (typically 24 h). One of the main concerns with using fixed-depth bottle incubations is whether stranding samples at fixed depths biases the measured CO 2 fixation relative to the 'true' in situ mixed conditions. Here we employ an individual based turbulence and photosynthesis model, which also accounts for photoacclimation and -inhibition, to examine whether the in vitro productivity estimates obtained from fixed-depth incubations are representative of the in situ productivity in a freely mixing water column. While previous work suggested that in vitro estimates could either over-or underestimate the in situ productivity, we show that the errors due to arresting the incubation bottles at fixed depths are indeed minimal. We present possible explanations for how previous authors could have arrived at contradictory results and discuss whether they might be artefacts related to the particular sampling protocol used. We discuss the errors associated with chlorophyll-based incubation methods for determining in situ phytoplankton growth rates in Ross et al. (2011; Mar Ecol Prog Ser 435:13-31).

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Section: Figuresupporting

confidence: 70%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

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Modelling the effect of vertical mixing on bottle incubations for determining in situ phytoplankton dynamics. II. Primary production

Ross¹,

Geider²,

Piera³

2011

Mar. Ecol. Prog. Ser.

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“…For instance, our in situ video observations highlighted the lower emission intensity of the cells due to photo-adaptation mechanisms in the stratified surface layer of the coastal stations. Variations in the environmental conditions (temperature, light intensity, nutrient concentration, vertical mixing…) result in changes in the photosynthesis activity and in the growth rates of phytoplankton populations (Macintyre et al 2000;Kononen et al 2003;Franklin et al 2009;Ross et al 2011a;Ross et al 2011b). In situ observation of these changes is now available by measuring the individual optical properties (size, fluorescence intensity) of phytoplankton cells, thanks to fluorescence and imaging methods.…”

Section: Discussionmentioning

confidence: 99%

In situ video and fluorescence analysis (VFA) of marine particles: applications to phytoplankton ecological studies.

Lunven¹,

Landeira²,

Lehaître³

et al. 2012

Limnology & Ocean Methods

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Phytoplankton consists of microscopic single-celled microalgae which transform, through the photosynthesis process, inorganic substances into organic biomass readily available to secondary consumers. Due to their role of primary producers, microalgae represent the basis of the marine food web. Phytoplankton is composed of a very high number of species that can be classified by functional groups (e.g., diatoms, dinoflagellates), size classes [pico-plankton (<2 µm), nano-plankton (2-20 µm), micro-plankton (> 20 µm)], or pigment composition (fucoxanthine, phycoerytrin, Chl a). In coastal areas, spatial and temporal variability of the phytoplanktonic community is very high and dependent on hydrographical conditions and physical processes. An increase in observation capacities is required to improve our knowledge of phytoplankton ecology and community patterns. Most of the environmental studies on phytoplankton ecology have used standard laboratory microscopic observations (Utermöhl 1958) to identify, enumerate, and classify phytoplankton species. This routine methodology is time-consuming and remains limited in comparison to the spatio-temporal resolution of physical/chemical sensors used during oceanographic in situ measurements. Thus, the need for automatic in situ methods giving relevant information on the plankton community structure has been clearly expressed by the scientific community.In situ video and fluorescence analysis (VFA) of marine particles: applications to phytoplankton ecological studies. AbstractRecent advances in laser and video technologies have enabled single particles to be visualized in aqueous solution. Here, we describe a new instrument enabling the analysis of the fluorescence signatures of marine particles directly in seawater: the Video Fluorescence Analyser (VFA). A field of view is produced inside a measurement chamber by a laser beam at 473 nm that illuminates a shallow region, 3500 µm deep. Individual cells or particles in this field appear as individual spots of light, which are clearly resolved by video against a dark background. The method can resolve particles ranging from 6 µm to several millimeters. The camera is equipped with mobile optical filters: band-pass filter, 520-580 nm, for phycoerythrin visualisation and high-pass filter, > 600 nm, for Chlorophyll a pigment. These filters are remotely controlled and displaced in front of the CCD camera, allowing imaging and discrimination between fluorescent particles. We report here experimental procedures and calibrations performed in the laboratory with phytoplankton cells (Dunaliella tertiolecta, Karenia mikimotoi, Pseudonitzschia australis) and calibrated fluorescent beads. Image analysis processing enabled particle counts, measurements, and size classification. The auto-fluorescence of individual particles was also tested in situ during a field cruise. In relation to other sensors, the VFA allowed particle enumeration and discrimination and detecting spatial variability of the phytoplankton size spectra in relation to hydrolog...

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Quantifying phytoplankton productivity and photoinhibition in the Ross Sea Polynya with large eddy simulation of Langmuir circulation

et al. 2017

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Southern Ocean phytoplankton assemblages acclimated to low‐light environments that result from deep mixing are often sensitive to ultraviolet and high photosynthetically available radiation. In such assemblages, exposures to inhibitory irradiance near the surface result in loss of photosynthetic capacity that is not rapidly recovered and can depress photosynthesis after transport below depths penetrated by inhibitory irradiance. We used a coupled biophysical modeling approach to quantify the reduction in primary productivity due to photoinhibition based upon experiments and observations made during the spring bloom in Ross Sea Polynya (RSP). Large eddy simulation (LES) was used to generate depth trajectories representative of observed Langmuir circulation that were passed through an underwater light field to yield time series of spectral irradiance representative of what phytoplankton would have experienced in situ. These were used to drive an assemblage‐specific photosynthesis‐irradiance model with inhibition determined from a biological weighting function and repair rate estimated from shipboard experiments on the local assemblage. We estimate the daily depth‐integrated productivity was 230 mmol C m−2. This estimate includes a 6–7% reduction in daily depth‐integrated productivity over potential productivity (i.e., effects of photoinhibition excluded). When trajectory depths were fixed (no vertical transport), the reduction in productivity was nearly double. Relative to LES estimates, there was slightly less depth‐integrated photoinhibition with random walk trajectories and nearly twice as much with circular rotations. This suggests it is important to account for turbulence when simulating the effects of vertical mixing on photoinhibition due to the kinetics of photodamage and repair.

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Modelling the effect of vertical mixing on bottle incubations for determining in situ phytoplankton dynamics. I. Growth rates

Cited by 27 publications

References 54 publications

Modelling the effect of vertical mixing on bottle incubations for determining in situ phytoplankton dynamics. II. Primary production

Modelling the effect of vertical mixing on bottle incubations for determining in situ phytoplankton dynamics. II. Primary production

In situ video and fluorescence analysis (VFA) of marine particles: applications to phytoplankton ecological studies.

Quantifying phytoplankton productivity and photoinhibition in the Ross Sea Polynya with large eddy simulation of Langmuir circulation

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