Solutions with Wright functions for time fractional convection flow near a heated vertical plate

Shakeel, Abdul; Ahmad, Sohail; Khan, Hamid; Vieru, Dumitru

doi:10.1186/s13662-016-0775-9

Cited by 15 publications

(7 citation statements)

References 18 publications

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“…Laplace transform technique was used, and the exact expressions for temperature, mass concentration, and velocity were presented in the forms of Fox-H function, General Wright function, and in the form of integral solutions using generalized function, respectively. Shakeel et al 18 Obtained exact solutions in terms of Wright functions for convection flow over a heated vertical plate via time fractional derivative approach. In addition, they computed numerical results using the subroutines of the software package Mathcad, and found that both exact and numerical solutions are in good agreement.…”

Section: Introductionmentioning

confidence: 99%

Influence of magnetic field on double convection problem of fractional viscous fluid over an exponentially moving vertical plate: New trends of Caputo time-fractional derivative model

Khan

Aleem

Imran

2019

Advances in Mechanical Engineering

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In this article, the influence of a magnetic field is studied on a generalized viscous fluid model with double convection, due to simultaneous effects of heat and mass transfer induced by temperature and concentration gradients. The fluid is considered over an exponentially accelerated vertical plate with time-dependent boundary conditions. Additional effects of heat generation and chemical reaction are also considered. A generalized viscous fluid model consists of three partial differential equations of momentum, heat, and mass transfer with corresponding initial and boundary condition. The idea of non-integer order Caputo time-fractional derivatives is used, and exact solutions for velocity, temperature, and concentration in terms of Wright function and function of Lorenzo–Hartley are developed for ordinary cases. Graphical analysis of flow and fractional parameters is made by using computational software MathCad, and discussed. The results obtained are also in good agreement with the published results from the literature. As a result, it is found that temperature and fluid velocity can be enhanced for smaller values of fractional parameters.

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Section: Introductionmentioning

confidence: 99%

Influence of magnetic field on double convection problem of fractional viscous fluid over an exponentially moving vertical plate: New trends of Caputo time-fractional derivative model

Khan

Aleem

Imran

2019

Advances in Mechanical Engineering

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“…Many researchers in fluid dynamics widely used fractional derivative models to study the viscoelastic materials such as polymers in glass transition. It is vital to bring in light the fact that fractional derivative generalizations of one dimensional viscoelastic models have seen to be more useful in modeling the response linear regime [10]. This generalization is in good agreement with the second law of thermodynamics.…”

Section: Introductionmentioning

confidence: 80%

Effect of Magnetic Field on Double Convection Flow of Viscous Fluid over a Moving Vertical Plate with Constant Temperature and General Concentration by using New Trend of Fractional Derivative

Hajizadeh¹,

Zeb²,

Ahmad³

et al. 2018

Open J. Math. Sci

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This article presents, effects of fractional order derivative and magnetic field on double convection flow of viscous fluid over a moving vertical plate with constant temperature and general concentration. The model is fractionalized by using Caputo-Fabrizio derivative operator. Closed form solutions of the fluid velocity, concentration and temperature are obtained by means of the Laplace transform. Numerical computations and graphical illustrations are used in order to study the effects of the Caputo-Fabrizio time-fractional parameter , magnetic parameter , Prandtl and Grashof numbers on velocity field.

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“…Recently Pandey [41] has discussed the applications of the LHGF to describe anomalous relaxation in dielectrics. We may also refer Mahmood et al [31], Saha et al [46], Shakeel et al [54], Singh et al [55], Zafar et al [61,62] etcetera. for some more recent applications of the LHGF.…”

Section: New Generalized Mittag-leffler Functionmentioning

confidence: 99%

On some computable solutions of unified families of fractional differential equations

Pandey

2021

São Paulo J. Math. Sci.

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In the present investigation after reviewing fractional derivatives and integrals, we study the Lorenzo-Hartley's G-function and its connections with other functions for fractional calculus. We propose some theorems pertaining to unified families of fractional differential equations involving Hilfer-Prabhakar derivative D , , , ,0+ . It is shown that a number of differential equations which arise during the study of different physical systems may be deduced from the unified families discussed in the current investigation. The computable solutions of fractional differential equations are obtained in closed forms of the Lorenzo-Hartley's G-function.

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Solutions with Wright functions for time fractional convection flow near a heated vertical plate

Cited by 15 publications

References 18 publications

Influence of magnetic field on double convection problem of fractional viscous fluid over an exponentially moving vertical plate: New trends of Caputo time-fractional derivative model

Influence of magnetic field on double convection problem of fractional viscous fluid over an exponentially moving vertical plate: New trends of Caputo time-fractional derivative model

Effect of Magnetic Field on Double Convection Flow of Viscous Fluid over a Moving Vertical Plate with Constant Temperature and General Concentration by using New Trend of Fractional Derivative

On some computable solutions of unified families of fractional differential equations

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