19 research outputs found
Algal biotechnology: real opportunities for Africa
Get PDFThe controlled and intense production of microalgae in photobioreactors has great potential for Africa. Of particular potential are; wastewater treatment, production of food and feed, production of bio-compounds, nutraceuticals and fine chemicals, and bioremediation. Microalgae have several competitive advantages over conventional crop production using agriculture and their biotechnology offers real economic potential. For the immediate future, products for the health food market and applications in bioremediation offer real opportunities for exploitation, environmental and economic benefits
The measurement of primary productivity in a high-rate oxidation pond (HROP)
Get PDFA high-rate oxidation pond is studied as a model system for comparing 14C and oxygen evolution methods as tools for measuring primary productivity in hypertrophic aquatic systems. Our results indicate that at very dense algal populations (up to 5 mg chl. a lâ1) and high photosynthetic rates, 14C based results may severely underestimate primary productivity, unless a way is found to keep incubation times very short. Results obtained with our oxygen electrode were almost an order of magnitude higher than those obtained by all 14C procedures. These higher values correspond fairly well with a field-tested computer-simulation model, as well as with direct harvest data obtained at the same pond when operated under similar conditions. The examination of the size-fractionation of the photosynthetic activity underscored the important contribution of nannoplanktonic algae to the total production of the syste
Photosynthetic characteristics of five high light and low light exposed microalgaea as measured with 14C-uptake and oxygen electrode techniques
Get PDF#Tetraselmis suecica, #Thalassiosira pseudonana, #Chaetoceros calcitrans, #Isochrysis galbana et #Microcystis sp.$ ont Ă©tĂ© utilisĂ©es pour dĂ©terminer leurs capacitĂ©s d'adaptation et pour tester les diffĂ©rences entre les deux mĂ©thodes de mesure. Les cultures avaient Ă©tĂ© exposĂ©es Ă un Ă©clairement fort (HL) ou Ă un Ă©clairement faible (LL) pendant deux jours avant l'expĂ©rience. L'efficacitĂ© de la conversion de la lumiĂšre (...) et l'activitĂ© photosynthĂ©tique spĂ©cifique maximale par unitĂ© de chlorophylle (...) ont Ă©tĂ© gĂ©nĂ©ralement plus Ă©levĂ©es pour les cultures LL. Les divers paramĂštres photosynthĂ©tiques mesurĂ©s par la mĂ©thode de l'Ă©lectrode Ă oxygĂšne ont Ă©tĂ© diffĂ©rents de ceux obtenus par celle du 14C. Les importantes diffĂ©rences de quotient photosynthĂ©tique (O2/CO2), observĂ©es aussi bien entre cultures HL et LL d'une mĂȘme espĂšce qu'entre espĂšces diffĂ©rentes, soulignent la difficultĂ© de convertir les productions d'oxygĂšne en assimilation de carbone. (D'aprĂšs rĂ©sumĂ© d'auteur
Photosynthetic characteristics of five high light and low light exposed microalgaea as measured with 14C-uptake and oxygen electrode techniques
No full text#Tetraselmis suecica, #Thalassiosira pseudonana, #Chaetoceros calcitrans, #Isochrysis galbana et #Microcystis sp.$ ont Ă©tĂ© utilisĂ©es pour dĂ©terminer leurs capacitĂ©s d'adaptation et pour tester les diffĂ©rences entre les deux mĂ©thodes de mesure. Les cultures avaient Ă©tĂ© exposĂ©es Ă un Ă©clairement fort (HL) ou Ă un Ă©clairement faible (LL) pendant deux jours avant l'expĂ©rience. L'efficacitĂ© de la conversion de la lumiĂšre (...) et l'activitĂ© photosynthĂ©tique spĂ©cifique maximale par unitĂ© de chlorophylle (...) ont Ă©tĂ© gĂ©nĂ©ralement plus Ă©levĂ©es pour les cultures LL. Les divers paramĂštres photosynthĂ©tiques mesurĂ©s par la mĂ©thode de l'Ă©lectrode Ă oxygĂšne ont Ă©tĂ© diffĂ©rents de ceux obtenus par celle du 14C. Les importantes diffĂ©rences de quotient photosynthĂ©tique (O2/CO2), observĂ©es aussi bien entre cultures HL et LL d'une mĂȘme espĂšce qu'entre espĂšces diffĂ©rentes, soulignent la difficultĂ© de convertir les productions d'oxygĂšne en assimilation de carbone. (D'aprĂšs rĂ©sumĂ© d'auteur
Exponential stabilization of magnetoelastic waves in a MindlinâTimoshenko plate by localized internal damping
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