A bifurcation-free interaction solution for steady separation from adownstream moving wall

An analysis is carried out to study the effect of heat and mass transfer on a non-Newtonian-fluid between two infinite parallel walls, one of them moving with a uniform velocity under the action of a transverse magnetic field. The moving wall moves with constant velocity in the direction of fluid flow while the free stream velocity is assumed to follow the exponentially increasing small perturbation law. Time-dependent wall suction is assumed to occur at permeable surface. The governing equations for the flow are transformed into a system of nonlinear ordinary differential equations by perturbation technique and are solved numerically by using the shooting technique with fourth order Runge-Kutta integration scheme. The effect of non-Newtonian parameter, magnetic pressure parameter, Schmidt number, Grashof number and modified Grashof number on velocity, temperature, concentration and the induced magnetic field are discussed. Numerical results are given and illustrated graphically for the considered Problem.

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Drag reduction of a nonnewtonian fluid by fluid injection on a moving wall

Archive of Applied Mechanics ◽

10.1007/s004190050215 ◽

1999 ◽

Vol 69 (3) ◽

pp. 215-225 ◽

Cited By ~ 35

Author(s):

M. Akçay ◽

M. Adil Yükselen

Keyword(s):

Drag Reduction ◽

Fluid Injection ◽

Moving Wall

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Porous layer impedance applied to a moving wall: Application to the radiation of a covered piston

The Journal of the Acoustical Society of America ◽

10.1121/1.2359233 ◽

2007 ◽

Vol 121 (1) ◽

pp. 206-213 ◽

Cited By ~ 6

Author(s):

Olivier Doutres ◽

Nicolas Dauchez ◽

Jean-Michel Génevaux

Keyword(s):

Porous Layer ◽

Moving Wall

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QUANTUM EFFECTS OF A DOMAIN WALL IN THE FERROMAGNETIC SYSTEM

Modern Physics Letters B ◽

10.1142/s0217984911025808 ◽

2011 ◽

Vol 25 (06) ◽

pp. 413-418

Author(s):

JI-SUO WANG ◽

KE-ZHU YAN ◽

BAO-LONG LIANG

Keyword(s):

Domain Wall ◽

Unitary Transformation ◽

Energy Levels ◽

Canonical Quantization ◽

Classical Equation ◽

Quantization Method ◽

Damping Term ◽

Quantum Energy ◽

Moving Wall ◽

Ferromagnetic System

Starting from the classical equation of the motion of a domain wall in the ferromagnetic systems, the quantum energy levels of the wall and the corresponding eigenfunctions in the case of considering damping term are given by using the canonical quantization method and unitary transformation. The quantum fluctuations of displacement and momentum of the moving wall has also been given as well as the uncertain relation.

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On the linear stability of compressible plane Couette flow

Journal of Fluid Mechanics ◽

10.1017/s0022112094003277 ◽

1994 ◽

Vol 258 ◽

pp. 131-165 ◽

Cited By ~ 24

Author(s):

Peter W. Duck ◽

Gordon Erlebacher ◽

M. Yousuff Hussaini

Keyword(s):

Linear Stability ◽

Couette Flow ◽

Small Amplitude ◽

Reynolds Numbers ◽

Inviscid Limit ◽

Plane Couette Flow ◽

Moving Wall ◽

Type Boundary ◽

The Stability ◽

Radiation Type

The linear stability of compressible plane Couette flow is investigated. The appropriate basic velocity and temperature distributions are perturbed by a small-amplitude normal-mode disturbance. The full small-amplitude disturbance equations are solved numerically at finite Reynolds numbers, and the inviscid limit of these equations is then investigated in some detail. It is found that instabilities can occur, although the corresponding growth rates are often quite small; the stability characteristics of the flow are quite different from unbounded flows. The effects of viscosity are also calculated, asymptotically, and shown to have a stabilizing role in all the cases investigated. Exceptional regimes to the problem occur when the wave speed of the disturbances approaches the velocity of either of the walls, and these regimes are also analysed in some detail. Finally, the effect of imposing radiation-type boundary conditions on the upper (moving) wall (in place of impermeability) is investigated, and shown to yield results common to both bounded and unbounded flows.

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N-soliton solutions and localized wave interaction solutions of a (3 + 1)-dimensional potential-Yu–Toda–Sasa–Fukuyamaf equation

Modern Physics Letters B ◽

10.1142/s0217984921502778 ◽

2021 ◽

pp. 2150277

Author(s):

Hongcai Ma ◽

Qiaoxin Cheng ◽

Aiping Deng

Keyword(s):

Dynamic Behavior ◽

Soliton Solution ◽

Soliton Solutions ◽

Wave Interaction ◽

Bilinear Transformation ◽

Interaction Solution ◽

Interaction Solutions ◽

Ytsf Equation ◽

Line Soliton

[Formula: see text]-soliton solutions are derived for a (3 + 1)-dimensional potential-Yu–Toda–Sasa–Fukuyama (YTSF) equation by using bilinear transformation. Some local waves such as period soliton, line soliton, lump soliton and their interaction are constructed by selecting specific parameters on the multi-soliton solutions. By selecting special constraints on the two soliton solutions, period and lump soliton solution can be obtained; three solitons can reduce to the interaction solution between period soliton and line soliton or lump soliton and line soliton under special parameters; the interaction solution among period soliton and two line solitons, or the interaction solution for two period solitons or two lump solitons via taking specific constraints from four soliton solutions. Finally, some images of the results are drawn, and their dynamic behavior is analyzed.

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Abundant Lump Solution and Interaction Phenomenon of (3+1)-Dimensional Generalized Kadomtsev–Petviashvili Equation

International Journal of Nonlinear Sciences and Numerical Simulation ◽

10.1515/ijnsns-2018-0034 ◽

2019 ◽

Vol 20 (1) ◽

pp. 33-40 ◽

Cited By ~ 4

Author(s):

Jianqing Lü ◽

Sudao Bilige ◽

Xiaoqing Gao

Keyword(s):

Symbolic Computation ◽

Bilinear Form ◽

Lump Solution ◽

Lump Solutions ◽

Interaction Solution ◽

Interaction Solutions ◽

Petviashvili Equation ◽

Contour Plots ◽

Special Case ◽

Interaction Phenomenon

AbstractIn this paper, with the help of symbolic computation system Mathematica, six kinds of lump solutions and two classes of interaction solutions are discussed to the (3+1)-dimensional generalized Kadomtsev–Petviashvili equation via using generalized bilinear form with a dependent variable transformation. Particularly, one special case are plotted as illustrative examples, and some contour plots with different determinant values are presented. Simultaneously, we studied the trajectory of the interaction solution.

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