0000000000117480

AUTHOR

Hervé Muhr

showing 2 related works from this author

Design of a reactor operating in supercritical water conditions using CFD simulations. Examples of synthesized nanomaterials

2011

International audience; Direct information about fluids under supercritical water conditions is unfeasible due to the engineering restrictions at high pressure and high temperature. Numerical investigations based on computational fluid dynamics (CFD) calculations are widely used in order to get extensive information on the fluid behavior, particularly to help the design of a new reactor. This paper presents the numerical investigations performed on an original supercritical water device, especially in the level of the reactor. CFD calculations allow to design and optimize the present reactor described in this study. Currently, this process produces some nanometric oxide powders in continuou…

Materials scienceCONTINUOUS HYDROTHERMAL SYNTHESISGeneral Chemical EngineeringNuclear engineeringOxideNanotechnology02 engineering and technologyComputational fluid dynamics010402 general chemistry7. Clean energy01 natural sciencesMIXERNanomaterialsCrystallinitychemistry.chemical_compoundNANOPOWDERSMETAL-OXIDE NANOPARTICLESNano-oxidesFluentPARTICLES[SPI.GPROC]Engineering Sciences [physics]/Chemical and Process EngineeringPhysical and Theoretical ChemistryHigh-resolution transmission electron microscopySupercritical waterNanomaterialsbusiness.industry[ SPI.GPROC ] Engineering Sciences [physics]/Chemical and Process Engineering021001 nanoscience & nanotechnologyCondensed Matter PhysicsCFD simulationsSupercritical fluid0104 chemical sciencesPowder synthesisNANOCRYSTALSchemistryScientific methodFluent0210 nano-technologybusiness
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CFD simulation of ZnO nanoparticle precipitation in a supercritical water synthesis reactor

2012

International audience; Continuous hydrothermal flow synthesis process has shown great advantages concerning the control of particle size and morphology through the optimization of supercritical water processing parameters. In particular, micromixing is a key issue of the process for controlling the nucleation mechanism. A Computational Fluid Dynamics (CFD) model is suggested for nanoparticle size determination using a population balance approach. Models for reaction kinetics, thermodynamics, nucleation and growth are presented. The effects of base concentration and hydrodynamics are investigated. Results show that the CFD may be valuable simulation tool for controlling the size and the sha…

CONTINUOUS HYDROTHERMAL SYNTHESISMaterials scienceFLOWGeneral Chemical EngineeringPopulationNucleationNanoparticleNanotechnologyCrystal growth02 engineering and technologyComputational fluid dynamicsVALIDATIONNANOPOWDERSMETAL-OXIDE NANOPARTICLES020401 chemical engineeringPARTICLE FORMATION0204 chemical engineeringPhysical and Theoretical Chemistryeducationeducation.field_of_studybusiness.industryFLUID-DYNAMICSAGGREGATION021001 nanoscience & nanotechnologyCondensed Matter PhysicsSupercritical fluidMicromixingChemical engineeringPOPULATION BALANCEParticle sizeCRYSTALLIZATION0210 nano-technologybusinessThe Journal of Supercritical Fluids
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