The scientist’s investigation covers issues in Thermodynamics, Mechanics, Membrane, Computational fluid dynamics and Heat transfer enhancement. The study incorporates disciplines such as Chemical engineering and Contact angle in addition to Membrane. His study explores the link between Chemical engineering and topics such as Chromatography that cross with problems in Sulfuric acid.
His Computational fluid dynamics research includes elements of Mechanical engineering and Turbulence. Within one scientific family, Masoud Rahimi focuses on topics pertaining to Hydraulic diameter under Heat transfer enhancement, and may sometimes address concerns connected to Nanofluid, Volumetric flow rate and Microchannel. He interconnects Nusselt number and Flow in the investigation of issues within Heat transfer.
Masoud Rahimi mainly investigates Mechanics, Analytical chemistry, Computational fluid dynamics, Volumetric flow rate and Heat transfer. His Mechanics study combines topics in areas such as Mixing and Micromixing. His research investigates the link between Computational fluid dynamics and topics such as Fluid dynamics that cross with problems in Pressure drop.
His Volumetric flow rate study which covers Composite material that intersects with Maximum power principle and Nanofluid. His Heat transfer research is included under the broader classification of Thermodynamics. He has included themes like Yield, Membrane and Chemical engineering in his Chromatography study.
Masoud Rahimi focuses on Chemical engineering, Microchannel, Composite material, Extraction and Volumetric flow rate. His study in Chemical engineering is interdisciplinary in nature, drawing from both Membrane, Biofouling and Aqueous solution. His study focuses on the intersection of Microchannel and fields such as Mass transfer with connections in the field of Pressure drop, Biological system, Chemical physics and Conical surface.
His Composite material research is multidisciplinary, incorporating perspectives in Coolant, Working fluid, Cavitation and Photovoltaic system, Maximum power principle. The concepts of his Volumetric flow rate study are interwoven with issues in Fluid dynamics, Micromixing, Heat transfer enhancement and Applied mathematics. His Heat transfer research is classified as research in Mechanics.
His main research concerns Murchison Widefield Array, Nanofluid, Water cooling, Composite material and Ferrofluid. His work carried out in the field of Water cooling brings together such families of science as Microchannel, Phase-change material and Photovoltaic system, Maximum power principle. His study looks at the intersection of Photovoltaic system and topics like Electric power with Sunflower oil.
His Sunflower oil research incorporates themes from Heat transfer and Natural circulation. Masoud Rahimi has researched Maximum power principle in several fields, including High frequency ultrasound, Coolant, Working fluid and Ultrasound energy. Ferrofluid is connected with Magnetic nanoparticles, Analytical chemistry, Rotational speed, Magnet and Volume in his study.
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Preparation of a novel antifouling mixed matrix PES membrane by embedding graphene oxide nanoplates
Sirus Zinadini;Ali Akbar Zinatizadeh;Masoud Rahimi;Vahid Vatanpour.
Journal of Membrane Science (2014)
Experimental and CFD studies on heat transfer and friction factor characteristics of a tube equipped with modified twisted tape inserts
Masoud Rahimi;Sayed Reza Shabanian;Ammar Abdulaziz Alsairafi.
Chemical Engineering and Processing (2009)
CFD modeling of flow and heat transfer in a thermosyphon
Asghar Alizadehdakhel;Masoud Rahimi;Ammar Abdulaziz Alsairafi.
International Communications in Heat and Mass Transfer (2010)
Novel high flux antifouling nanofiltration membranes for dye removal containing carboxymethyl chitosan coated Fe3O4 nanoparticles
S. Zinadini;A.A. Zinatizadeh;M. Rahimi;V. Vatanpour.
FIRST SEASON MWA EOR POWER SPECTRUM RESULTS at REDSHIFT 7
A.P. Beardsley;A.P. Beardsley;B. J. J. Hazelton;I.S. Sullivan;P. Carroll.
The Astrophysical Journal (2016)
Viscosity of pure carbon dioxide at supercritical region: Measurement and correlation approach
Ehsan Heidaryan;Tahmas Hatami;Masoud Rahimi;Jamshid Moghadasi.
Journal of Supercritical Fluids (2011)
Optimization of biodiesel production from soybean oil in a microreactor
Masoud Rahimi;Masoud Rahimi;Babak Aghel;Mohammad Alitabar;Arash Sepahvand.
Energy Conversion and Management (2014)
Heat transfer enhancement in a PV cell using Boehmite nanofluid
Nooshin Karami;Masoud Rahimi.
Energy Conversion and Management (2014)
CFD and experimental studies on heat transfer enhancement in an air cooler equipped with different tube inserts
S.R. Shabanian;M. Rahimi;M. Shahhosseini;A.A. Alsairafi.
International Communications in Heat and Mass Transfer (2011)
New correlations to predict natural gas viscosity and compressibility factor
Ehsan Heidaryan;Jamshid Moghadasi;Masoud Rahimi.
Journal of Petroleum Science and Engineering (2010)
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