Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation

Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation

We study the boundary layer characteristics of heat and mass transfer flow past a vertical wedge in the presence of thermal radiation. The surface temperature and the species concentration are assumed to be oscillating in the magnitude but not in the direction of oncoming flow velocity. The governin...

Full description

Bibliographic Details
Main Authors: Firoza M.N., Roy N.C., Hossain Md. A.
Format: Article
Language:English
Published: Sciendo 2017-08-01
Series:International Journal of Applied Mechanics and Engineering
Subjects:
mixed convection
thermal radiation
vertical wedge
Online Access:https://doi.org/10.1515/ijame-2017-0035
id doaj-9f67d000069c4f1a8c37335d4c75c8d4
record_format Article
spelling doaj-9f67d000069c4f1a8c37335d4c75c8d42021-09-05T20:51:07ZengSciendoInternational Journal of Applied Mechanics and Engineering1734-44922353-90032017-08-0122353956510.1515/ijame-2017-0035ijame-2017-0035Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal RadiationFiroza M.N.0Roy N.C.1Hossain Md. A.2Department of Mathematics, University of Dhaka, Dhaka1000, BangladeshDepartment of Mathematics, University of Dhaka, Dhaka1000, BangladeshDepartment of Mathematics, University of Dhaka, Dhaka1000, BangladeshWe study the boundary layer characteristics of heat and mass transfer flow past a vertical wedge in the presence of thermal radiation. The surface temperature and the species concentration are assumed to be oscillating in the magnitude but not in the direction of oncoming flow velocity. The governing equations have been solved by two distinct methods, namely, the straightforward finite difference method for the entire frequency range, and the series solution for the low frequency range and the asymptotic series expansion method for the high frequency range. Numerical solutions have been presented in terms of the amplitudes and phase angles of the skin friction, the rate of heat transfer and the mass transfer with the variations of Richardson’s number, the Prandtl number, the conduction–radiation parameter, the surface temperature parameter and the Schmidt number. Furthermore, the effects of these parameters are examined in terms of the transient skin friction, heat transfer and mass transfer.https://doi.org/10.1515/ijame-2017-0035mixed convectionthermal radiationvertical wedge
collection DOAJ
language English
format Article
sources DOAJ
author Firoza M.N.
Roy N.C.
Hossain Md. A.
spellingShingle Firoza M.N.
Roy N.C.
Hossain Md. A.
Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation
International Journal of Applied Mechanics and Engineering
mixed convection
thermal radiation
vertical wedge
author_facet Firoza M.N.
Roy N.C.
Hossain Md. A.
author_sort Firoza M.N.
title Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation
title_short Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation
title_full Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation
title_fullStr Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation
title_full_unstemmed Conjugate Heat and Mass Transfer on Fluctuating Mixed Convection Flow along a Vertical Wedge with Thermal Radiation
title_sort conjugate heat and mass transfer on fluctuating mixed convection flow along a vertical wedge with thermal radiation
publisher Sciendo
series International Journal of Applied Mechanics and Engineering
issn 1734-4492
2353-9003
publishDate 2017-08-01
description We study the boundary layer characteristics of heat and mass transfer flow past a vertical wedge in the presence of thermal radiation. The surface temperature and the species concentration are assumed to be oscillating in the magnitude but not in the direction of oncoming flow velocity. The governing equations have been solved by two distinct methods, namely, the straightforward finite difference method for the entire frequency range, and the series solution for the low frequency range and the asymptotic series expansion method for the high frequency range. Numerical solutions have been presented in terms of the amplitudes and phase angles of the skin friction, the rate of heat transfer and the mass transfer with the variations of Richardson’s number, the Prandtl number, the conduction–radiation parameter, the surface temperature parameter and the Schmidt number. Furthermore, the effects of these parameters are examined in terms of the transient skin friction, heat transfer and mass transfer.
topic mixed convection
thermal radiation
vertical wedge
url https://doi.org/10.1515/ijame-2017-0035
work_keys_str_mv AT firozamn conjugateheatandmasstransferonfluctuatingmixedconvectionflowalongaverticalwedgewiththermalradiation
AT roync conjugateheatandmasstransferonfluctuatingmixedconvectionflowalongaverticalwedgewiththermalradiation
AT hossainmda conjugateheatandmasstransferonfluctuatingmixedconvectionflowalongaverticalwedgewiththermalradiation
_version_ 1717784253298638848

Similar Items