A numerical study of double-diffusive convection in the anisotropic porous layer under rotational modulation with internal heat generation

•Rotational modulation effects on heat and mass transport in porous medium is explained.•Nusselt and Sherwood numbers were used to quantify heat and mass.•Block hybrid method is used to solve the Lorenz equations.•The rotational modulation was found to affect the stability of the system. Double-diff...

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Bibliographic Details
Published in:International communications in heat and mass transfer 2022-10, Vol.137, p.106266, Article 106266
Main Authors: Ali, Samah A., Rudziva, Munyaradzi, Sibanda, Precious, Noreldin, Osman A.I., Goqo, Sicelo P., Mthethwa, Hloniphile Sithole
Format: Article
Language:English
Subjects:
Block hybrid method
Heat and mass transfer
Porous Media
Rotation
Stability analysis
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Summary:•Rotational modulation effects on heat and mass transport in porous medium is explained.•Nusselt and Sherwood numbers were used to quantify heat and mass.•Block hybrid method is used to solve the Lorenz equations.•The rotational modulation was found to affect the stability of the system. Double-diffusive convection in a non-uniformly rotating anisotropic fluid layer with internal heating is investigated. The normal mode technique is used to obtain the critical stationary and oscillatory Rayleigh numbers. The analysis for the nonlinear case is based on minimal truncated double Fourier series which gives rise to the nonlinear Lorenz type equations. A local quasilinearization block hybrid method (LQBHM) is employed to solve the coupled nonlinear Lorenz type equations. The solution obtained using this method is compared with solutions obtained using the ode45 solver. The numerical results indicate that the LQBHM is accurate, efficient, and flexible. A weakly nonlinear analysis is used to investigate the rate of heat and mass transfer in the fluid system. The effects of time varying rotation, internal heat generation, anisotropy parameters, concentration Rayleigh, Vadasz, and Lewis numbers on the heat and mass transfer are shown graphically. Among other results, the quantitative relationships for rotational modulation amplitude and internal heat generation are [Nu/Sh]δ1=0.2
ISSN:0735-1933
1879-0178
DOI:10.1016/j.icheatmasstransfer.2022.106266