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dc.date.accessioned2024-12-04T19:08:54Z
dc.date.available2024-12-04T19:08:54Z
dc.date.issued2024-11-21es_MX
dc.identifier.isbn9780443140587es_MX
dc.identifier.urihttps://cathi.uacj.mx/20.500.11961/29305
dc.description.abstractModeling of algal bioreactors shows a crescent interest by the potential of algal biomass as a renewable source of energy. Bioreactors may accelerate the algal growth for applications like bioenergy. This process requires uptaking a nutrient through algal inner or surface, which defines the kinetics of algal energy conversion. The ways account for direct and indirect biophotolysis, fermentation either dark or light, and electrochemical either photo- or electrolytic. Considering the first way, algal capacity of fixing a nutrient using sunlight as a photosynthetic organism is attractive, compared with former biofuels that used cane or crops as a source of biomass. In this sense, light transmission is a premise for the success of algal photobioreactors, open and closed. However, control is needed to optimize light transmission and algal motion in water, which naturally allows algal growth through its dispersion. Therefore, understanding photobioreactor hydrodynamics is crucial to make algal growth an efficient process, such as developing new techniques to improve both biomass productivity and energy harvesting. For instance, a centrally illuminated vortex reactor may compete with a parallel plate, which is the most studied photobioreactor. Recent studies showed that a rotating-cylinder promotes Taylor–Couette vortex flow with less energy-consuming in square-section reactors, than using pallets impellors or baffles. Furthermore, this reactor may enhance the exposure of culture to light and increase mass and heat transfer due to controlled flow dynamics. The reactor size and design impacts algal growth and performance.es_MX
dc.description.urihttps://www.sciencedirect.com/science/article/abs/pii/B9780443140587000166?via%3Dihubes_MX
dc.language.isoenes_MX
dc.publisherElsevieres_MX
dc.relation.ispartofProducto de investigación IITes_MX
dc.relation.ispartofInstituto de Ingeniería y Tecnologíaes_MX
dc.subjectagales_MX
dc.subjectCFDes_MX
dc.subject.otherinfo:eu-repo/classification/cti/7es_MX
dc.titleComputational analysis and modeling of algal bioreactors performancees_MX
dc.typeCapítulo de libroes_MX
dcterms.thumbnailhttp://ri.uacj.mx/vufind/thumbnails/rupiiit.pnges_MX
dcrupi.institutoInstituto de Ingeniería y Tecnologíaes_MX
dcrupi.cosechableSies_MX
dcrupi.subtipoInvestigaciónes_MX
dcrupi.nopagina189-204es_MX
dcrupi.alcanceInternacionales_MX
dcrupi.paisEstados Unidoses_MX
dc.identifier.doihttps://doi.org/10.1016/B978-0-443-14058-7.00016-6es_MX
dc.contributor.coauthorCarrillo Pereyra, Francisco
dcrupi.titulolibroAlgal Bioreactorses_MX
dc.contributor.authorexternoSierra Espinosa, Fernando
dc.contributor.coauthorexternoGraciano, Dulce
dcrupi.colaboracionextnoes_MX
dcrupi.impactosocialnoes_MX
dcrupi.vinculadoproyextnoes_MX
dcrupi.pronacesEnergía y Cambio Climáticoes_MX
dcrupi.vinculadoproyintnoes_MX


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