2009
DOI: 10.5194/bg-6-1199-2009
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Effects of the pH/<i>p</i>CO<sub>2</sub> control method on medium chemistry and phytoplankton growth

Abstract: Abstract. The control of key chemical parameters in phytoplankton cultures, such as pCO 2 , pH and (the saturation state of calcium carbonate), is made difficult by the interdependence of these parameters and by the changes resulting from the growth of the organisms, such as CO 2 fixation, nutrient uptake and, for coccolithophores, calcite precipitation. Even in cultures where pCO 2 or pH is maintained constant, other chemical parameters change substantially at high cell densities. Experimentally we observed t… Show more

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Cited by 164 publications
(168 citation statements)
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“…CO 2 -enriched seawater was added to the high-CO 2 treatment replicates every 24 h, acclimating the natural phytoplankton population to increments of elevated pCO 2 from ambient to ∼ 800 µatm over 8 days followed by maintenance at ∼ 800 µatm as per the method described by Schulz et al (2009). Adding CO 2 -enriched seawater is the preferred protocol, since some phytoplankton species are inhibited by the mechanical effects of direct bubbling (Riebesell et al, 2010;Shi et al, 2009), which causes a reduction in growth rates and the formation of aggregates (Love et al, 2016). pH was monitored daily to adjust the pCO 2 of the experimental media (+/−) prior to dilutions to maintain target pCO 2 levels in the incubation bottles.…”
Section: Perturbation Experiment Sampling and Experimental Setupmentioning
confidence: 99%
“…CO 2 -enriched seawater was added to the high-CO 2 treatment replicates every 24 h, acclimating the natural phytoplankton population to increments of elevated pCO 2 from ambient to ∼ 800 µatm over 8 days followed by maintenance at ∼ 800 µatm as per the method described by Schulz et al (2009). Adding CO 2 -enriched seawater is the preferred protocol, since some phytoplankton species are inhibited by the mechanical effects of direct bubbling (Riebesell et al, 2010;Shi et al, 2009), which causes a reduction in growth rates and the formation of aggregates (Love et al, 2016). pH was monitored daily to adjust the pCO 2 of the experimental media (+/−) prior to dilutions to maintain target pCO 2 levels in the incubation bottles.…”
Section: Perturbation Experiment Sampling and Experimental Setupmentioning
confidence: 99%
“…Estimates of CO 2 tolerance under laboratory conditions may also be influenced by experimental acclimation periods (Trimborn et al, 2014;Hennon et al, 2015;Torstensson et al, 2015;Li et al, 2017a), differences in experimental conditions (e.g. nutrients, light climate) (Hoppe et al, 2015;Hong et al, 2017;Li et al, 2017b), methods of CO 2 manipulation (Shi et al, 2009;Gattuso et al, 2010), and region-specific environmental adaptations (Schaum et al, 2012). Thus, investigations on natural communities are essential in order to better understand the outcome of these complex interactions.…”
mentioning
confidence: 99%
“…Ocean acidification generally decreases calcification by coccolithophores (Riebesell et al, 2000;Zondervan et al, 2002;Delille et al, 2005;Beaufort et al, 2011) and other calcifying algae (Gao and Zheng, 2010;Sinutok et al, 2011), with responses differing across species or different environmental conditions (Langer et al, 2006(Langer et al, , 2009Iglesias-Rodriguez et al, 2008;Doney et al, 2009;Shi et al, 2009). Algal calcification, in turn, influences the impacts of solar ultraviolet radiation (UVR; 280-400 nm) on the algae's photophysiology Gao and Zheng, 2010;Guan and Gao, 2010).…”
mentioning
confidence: 99%