Entropy analysis of MHD fluid flow over a curved stretching sheet

Entropy generation due to fluid friction and heat transfer over a curved impermeable stretching sheet in the presence of an applied magnetic field is investigated. Similarity solutions of the fluid velocity and temperature are obtained. The effects of the curvature and magnetic field strength on the...

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Hauptverfasser:	Narla, V. K., Biswas, Chandan, Rao, G. Ananda
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Dimensionless numbers Entropy Field strength Flow resistance Fluid dynamics Fluid flow Fluid friction Heat transfer Magnetic fields Optimization Similarity solutions Stretching Temperature gradients Viscosity
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creator	Narla, V. K. Biswas, Chandan Rao, G. Ananda
description	Entropy generation due to fluid friction and heat transfer over a curved impermeable stretching sheet in the presence of an applied magnetic field is investigated. Similarity solutions of the fluid velocity and temperature are obtained. The effects of the curvature and magnetic field strength on the flow and heat transfer characteristics are presented through graphs. The dimensionless entropy generation number and Bejan number are derived using velocity and temperature gradients. The minimization of entropy generation and minimization of fluid flow resistance by geometry and magnetic strength is identified.
doi_str_mv	10.1063/5.0014560
format	Conference Proceeding
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K. ; Biswas, Chandan ; Rao, G. Ananda</creator><contributor>Doodipalla, Mallikarjuna Reddy ; Pasham, Narasimha Swamy ; Malaraju, Changal Raju ; Karanamu, Maruthi Prasad ; Sheri, Siva Reddy</contributor><creatorcontrib>Narla, V. K. ; Biswas, Chandan ; Rao, G. Ananda ; Doodipalla, Mallikarjuna Reddy ; Pasham, Narasimha Swamy ; Malaraju, Changal Raju ; Karanamu, Maruthi Prasad ; Sheri, Siva Reddy</creatorcontrib><description>Entropy generation due to fluid friction and heat transfer over a curved impermeable stretching sheet in the presence of an applied magnetic field is investigated. Similarity solutions of the fluid velocity and temperature are obtained. The effects of the curvature and magnetic field strength on the flow and heat transfer characteristics are presented through graphs. The dimensionless entropy generation number and Bejan number are derived using velocity and temperature gradients. 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identifier	ISSN: 0094-243X
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language	eng
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source	AIP Journals Complete
subjects	Dimensionless numbers Entropy Field strength Flow resistance Fluid dynamics Fluid flow Fluid friction Heat transfer Magnetic fields Optimization Similarity solutions Stretching Temperature gradients Viscosity
title	Entropy analysis of MHD fluid flow over a curved stretching sheet
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