about
Conversion of CO2 into biomass by microalgae: how realistic a contribution may it be to significant CO2 removal?Biotechnological production of lutein and its applications.Wastewater treatment using microalgae: how realistic a contribution might it be to significant urban wastewater treatment?Modeling of photosynthesis and respiration rate for Isochrysis galbana (T-Iso) and its influence on the production of this strain.Selection of native Tunisian microalgae for simultaneous wastewater treatment and biofuel production.Medium recycling for Nannochloropsis gaditana cultures for aquaculture.A low-cost culture medium for the production of Nannochloropsis gaditana biomass optimized for aquaculture.Use of secondary-treated wastewater for the production of Muriellopsis sp.Lovastatin inhibits its own synthesis in Aspergillus terreus.Utilization of secondary-treated wastewater for the production of freshwater microalgae.Genetic algorithm for the medium optimization of the microalga Nannochloropsis gaditana cultured to aquaculture.A quantitative study of eicosapentaenoic acid (EPA) production by Nannochloropsis gaditana for aquaculture as a function of dilution rate, temperature and average irradiance.A model for light distribution and average solar irradiance inside outdoor tubular photobioreactors for the microalgal mass culture.Biomass and lutein productivity of Scenedesmus almeriensis: influence of irradiance, dilution rate and temperature.Improvement of stability and carotenoids fraction of virgin olive oils by addition of microalgae Scenedesmus almeriensis extracts.Utilization of Anabaena sp. in CO₂ removal processes: modelling of biomass, exopolysaccharides productivities and CO₂ fixation rate.Influence of power supply in the feasibility of Phaeodactylum tricornutum cultures.Assessment of the production of 13C labeled compounds from phototrophic microalgae at laboratory scale.Development of a process for the production of L-amino-acids concentrates from microalgae by enzymatic hydrolysis.Effect of pretreatments on biogas production from microalgae biomass grown in pig manure treatment plants.A whole biodiesel conversion process combining isolation, cultivation and in situ supercritical methanol transesterification of native microalgae.Evaluation of native microalgae from Tunisia using the pulse-amplitude-modulation measurement of chlorophyll fluorescence and a performance study in semi-continuous mode for biofuel productionAcyl lipid composition variation related to culture age and nitrogen concentration in continuous culture of the microalga Phaeodactylum tricornutumAnalysis of light regime in continuous light distributions in photobioreactorsThe oxygen evolution methodology affects photosynthetic rate measurements of microalgae in well-defined light regimesDevelopment of a process for efficient use of CO2 from flue gases in the production of photosynthetic microorganismsDevelopment of a process for large-scale purification of C-phycocyanin from Synechocystis aquatilis using expanded bed adsorption chromatographyObtaining lutein-rich extract from microalgal biomass at preparative scaleUtilization of the cyanobacteria Anabaena sp. ATCC 33047 in CO2 removal processesEvaluation of flocculants for the recovery of freshwater microalgaeMixotrophic growth of Phaeodactylum tricornutum on fructose and glycerol in fed-batch and semi-continuous modesPreparative Recovery of Carotenoids from Microalgal BiomassEvaluation of photosynthetic light integration by microalgae in a pilot-scale raceway reactor
P50
Q34295999-2F62E643-8CCC-42CF-8F86-A0ABB88F1DDAQ37679006-6CA672B6-BB9B-46C0-B795-2E277FBB4B09Q38958832-8DCD6DF1-E984-4F6E-96E2-B29449DE25E0Q40152994-A57834B5-C792-44A6-A28A-489B1E64835CQ43339072-4F7D8E45-1944-474B-95C9-F72B85F0B214Q43353118-F1E85AA9-A05D-4050-BFCB-50FFD3C0F41FQ43445731-1FF8566C-2C98-4C00-8892-95892844D5B0Q43806581-47C31455-FBCA-4F35-AC43-7B4B9C8B044BQ44739908-BC36CBF9-A1E7-431F-8A4D-4B038FC03BE0Q46720456-7A108E89-DC07-47DC-8CAD-6FD5C28074E3Q46802314-7C41C45B-0B43-490D-ADEA-C7EEAAD71619Q46962050-88424E87-ED31-4451-B6F0-F54310532342Q47445817-4848CDEB-1120-49CD-BD90-237F29A4AFC1Q47696534-F78C5A13-5427-40E3-9F3D-0D5481A0FDFAQ51018724-022D9C21-0E03-4F2B-B2D0-FFDAF39AEF2FQ51416279-BF52D5C3-BCDA-4168-87C4-6A32E5A6B3C7Q51627451-AF427A6A-8473-44BF-A147-C4FFB48027D4Q51836353-DA3122A5-11D5-4C4D-89CA-9DBE4D94AC84Q52623098-57CA4269-1504-4242-9E53-8D511214BA19Q52684804-92B799F4-042A-4B51-9371-5449BD9D19B9Q53800641-4E35B219-D4F1-4FAE-A41C-71E5A7E72251Q64057588-3578D5D0-40CA-4072-BAD4-2F51028CCA07Q74158354-DE967564-53B4-47B4-B40A-713C18E4F4A4Q82443718-88EDA1D7-EE0E-4A7F-A494-C894A1B7C3B1Q82598302-261B152E-4500-4FAD-BF91-E9128977A16AQ83263021-4E3F8636-7565-40DC-8565-86B4964CCB42Q83365797-C9331347-F584-4672-B2CC-032DFFBD7B15Q84205586-A9009953-A3A4-4698-9CE2-ADBA326EF7C1Q84333668-6B656672-F838-4815-97A8-C05958682E3AQ84392476-3A91D644-DF3F-494D-9A68-D866A948B280Q85648385-6AB3374C-26D8-4C97-A839-55D61B9F0235Q90954305-8F49C7B6-0A63-49A0-873C-14E2C52F08B8Q91740812-2B442805-D6E2-4C87-9528-64880CC8EFCB
P50
description
researcher
@en
wetenschapper
@nl
name
José M Fernández Sevilla
@en
José M Fernández Sevilla
@nl
type
label
José M Fernández Sevilla
@en
José M Fernández Sevilla
@nl
prefLabel
José M Fernández Sevilla
@en
José M Fernández Sevilla
@nl
P106
P31
P496
0000-0002-0290-5810