Startseite A reliable analytical approach for a fractional model of advection-dispersion equation
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A reliable analytical approach for a fractional model of advection-dispersion equation

  • Jagdev Singh EMAIL logo , Aydin Secer , Ram Swroop und Devendra Kumar
Veröffentlicht/Copyright: 4. Juni 2018
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Nonlinear Engineering
Aus der Zeitschrift Nonlinear Engineering Band 8 Heft 1

Abstract

Empirical investigations of solute fate and carrying in streams and rivers often contain inventive liberate of solutes at an upstream perimeter for a finite interval of time. An analysis of various worth references on surface-water-grade mathematical formulation reveals that the logical solution to the continual-parameter advection- dispersion problem for this type of boundary state has been generally missed. In this work, we study the q-fractional homotopy analysis transform method (q-FHATM) to find the analytical and approximate solutions of space-time arbitrary order advection-dispersion equations with nonlocal effects. The diagrammatical representation is done by using Maple package, which enhance the discretion and stability of family of q-FHATM series solutions of fractional advection-dispersion equations. The efficiency of the applied technique is demonstrated by using three numerical examples of space- and time-fractional advection-dispersion equations.

Keywords: Fractional advection-dispersion problem; Laplace transform method; q-fractional homotopy analysis transform technique; Mittage-Leffler function

1 Introduction

Numerous modern water-quality related problems contain usability and importance of the advection dispersion problems. The advection-dispersion problems involving particular initial and boundary limitations narrate spatial and temporal differences in solute concentration. An elementary and general form of the governing equation familiar as the advection-dispersion equation may be obtained for the instance of stable, consistent flow and spatially constant model specification. Fractional calculus has been succeeding in attaining continuous popularity among researchers, due to its applications in engineering, science, finance and other fields, after describing the half order (α = 1/2) derivative by Leibniz in 30 September 1695 [1]. Number of scientists investigated the concept of derivatives and integrals of arbitrary order for instance Caputo, Liouville, Grunewald, Letnikov, Riemann, etc. An excellent literature and approaches of fractional operators for differentiation and integration can be found in [2, 3]. In recent years differential equations of fractional order have gained popularity due to its significant applications [4, 5, 6, 7, 8, 9, 10, 11, 12]. The fractional advection-dispersion equation is investigated by number of methods which are the special case of q-FHATM solution such as fractional variational iteration technique [13], Adomian decomposition approach [14], homotopy perturbation algorithm [15, homotopy analysis technique [16], etc.

In this work, we discuss the existence of an efficient technique called q-fractional homotopy analysis transform method (q-FHATM), is a powerful composition of q-HAM with well-known Laplace transform to analyze space- and time- fractional advection-dispersion equations (STFADE). The coupling of q-HAM with Laplace transform giving time consuming con-sequences and less C.P.U time (Processor 2.65 GHz or more and RAM-1 GB or more) to obtain the numerical solution for nonlinear problems of integer or fractional orders. The advantage of this q-FHATM is its capability to obtaining the series solution of STFADE’s at large domain by choosing the approximate values of parameters and n. The q-HAM was proposed by El-Tavil and Huseen [17, 18] is more general than classical homotopy analysis method (HAM). The HAM was introduced and implied by Liao [19, 20] is an analytical approach to investigate several kinds of problems occurring in engineering, science and finance such as nonlinear equations occurring in heat transfer [21], fractional differential-difference equation [22], etc. In recent years analytical techniques are also combined with Laplace transform to study the various nonlinear problems such as Blasius flow equations [23], fractional biological population model [24], fractional Lotka-Volterra equation arising in biological systems [25], Klein-Gordon equations [26], singular system of transistor circuits [27], fractional coupled Burgers equations [28], fractional Rosenau-Hyman equation [29], linear differential equations of fractional orders [30], etc. In addition to this there are numerous methods have been employed to handle various problems of integer or fractional order [31, 32, 33, 34, 35, 36, 37, 38, 39].

In this work, we examine the space- and time- fractional advection-dispersion problem characterized as

αctα=wβcxβ+k2βcx2β,t>0,x>0,0<α,β1(1)

having the initial conditions

c(0,t)=ξ1(t),cx(0,t)=ξ2(t),c(x,0)=f(x),(2)

here c= c(x,t) is standing for the concentration of contaminant, x is indicating the spatial space region, t is denoting time, α, β are representing the parameters narrating the order of the time- and space- arbitrary ordered differential coefficients, respectively, w is indicating the average fluid velocity and k is standing for the dispersion coefficient.

2 Basic definitions

Definition 1

The fractional derivative of ϕ(t) defined by Caputo [40] is represented as:

Dβϕ(t)=JmβDmϕ(t)=1Γ(mβ)0t(tτ)mβ1ϕm(τ)dτ,(3)

for m – 1 < βm, mN, t > 0.

Definition 2

The Laplace transform (LT) of the fractional ordered differential coefficient in Caputo sense is defined as follows

L[Dβϕ(t)]=sβL[ϕ(t)]r=0n1sβr1ϕ(r)(0+),n1<βn.(4)

Definition 3

The LT of the fractional integral in Riemann-Liouville sense is represented as

L[Itβϕ(t)]=sβϕ¯(s).(5)

Definition 4

The well known Mittag-Leffler (M-L) function is given as [41]:

Eβ(z)=k=0zkΓ(βk+1)(βC,Re(β)>0).(6)

3 Basic idea of q-FHATM

To demonstrate the fundamental structure of proposed algorithm, we discuss a nonlinear partial differential equation of fractional order of the form:

Dtβc(x,t)+Rc(x,t)+Nc(x,t)=h(x,t),n1<βn(7)

In the above fractional differential equation Dtβc is denoting the fractional differential coefficient termed in Caputo sense of the function c,R represents the linear differential operator, N indicates the general nonlinear differential operator and h(x,t) shows the term occurring from source.

By employing the LT operator on Equation (7), we get

L[Dtβc]+L[Rc]+L[Nc]=L[h(x,t)].(8)

Now, applying the differentiation formula of the LT operator, we get

sβL[c]k=0n1sβk1c(k)(x,0)+L[Rc]+L[Nc]=L[h(x,t)].(9)

On simplifying

L[c]1sβk=0n1sβk1c(k)(x,0)+1sβ[L[Rc]+L[Nc]L[h(x,t)]]=0.(10)

We present the nonlinear operator in the following way

N[Ψ(x,t;q)]=L[Ψ(x,t;q)]1sβk=0n1sβk1Ψ(k)(x,t;q)(0+)+1sβ[L[RΨ(x,t;q)]+L[NΨ(x,t;q)]L[h(x,t)]].(11)

In the above equation q belongs in the closed interval [0, 1/n] and Ψ(x,t;q) indicates a real function, which depends upon the variables x,t and q. We define a homotopy in the following way

(1nq)L[Ψ(x,t;q)c0(x,t)]=qN[c(x,t)].(12)

In the above homotopy equation L indicates the LT operator, n ≥ 1, ≠ 0 stands for an auxiliary parameter, c0(x, t) is an initial guess of c(x, t) and Ψ(x, t; q) is a unknown function. It is obvious that, when we set the value of embedding parameter q = 0 and q = 1n it yields the following results

Ψ(x,t;q)=c0(x,t),Ψ(x,t;1n)=c(x,t),(13)

respectively. Hence, when q enhances from 0 to 1n , the solution Ψ(x, t; q) changes from the initial guess c0(x, t) to the solution c(x, t). Enlarging Ψ(x, t; q) in series form using Taylor’s Theorem about q, we get

Ψ(x,t;q)=m=0cm(x,t)qm.(14)

In the Eq. (14), the value of cm(x, t) is obtained from

cm(x,t)=1mmΨ(x,t;q)qm|q=0.(15)

After properly choosing the value of initial guess c0(x, t), the parameters n and the series given in Eq. (14) converges at q = 1n then we get

c(x,t)=m=0cm(x,t)1nm.(16)

The original nonlinear equations must contain Eq. (16) as one of its solution. The governing equation can be obtained from Eq. (12) on consideration of Eq. (16).

Set the vectors

cm={c0,c1,,cm}.(17)

On differentiation of Eq. (12) m-times about q and dividing by m!, and putting q = 0, the deformation equation of mth-order is obtained as

L[cm(x,t)kmcm1(x,t)]=Rm(cm1).(18)

Applying the inverse LT operator, we get

cm(x,t)=kmcm1(x,t)+L1[Rm(cm1)].(19)

In the above equation the value of 𝓡m (C⃗m–1) is derived as follows

Rm(cm1)=1(m1)!m1N[Ψ(x,t;q)]qm1|q=0,(20)

and

km=0,m1,n,m>1.(21)

From study it should be analyzed that in special case n = 1, q-FHATM directly convert to classical homotopy analysis method (HAM) i.e. HAM (q-FHATM, n = 1).

3.1 Convergence analysis

To prove the convergence of the solution, first of all we need to give some conditions that are needed to verify the convergence of the series (16). These are discussed in [18] via the following stated theorem.

Theorem 1

Let us suppose that the components c0, c1, c2,… of the solution can be written as given in Eq. (18). In the series solution m=0cm1nm presented in Eq. (16), converges if there exists 0 < λ < n s. t. ‖cm+1 ‖ ≤ λncm‖ for all mm0 for some m0N.

Additionally, the estimation error is given by

cm=0Mcm1nmλnM+11λn||c0||.

4 Numerical examples

In this portion, we examine the space- and time- fractional advection dispersion problems with the aid of aforesaid reliable q-FHATM algorithm in a realistic and convenient way.

Example 1

We discuss the advection dispersion equation of fractional order given as follows

αctα=wcx+k2cx2,t>0,x>0,0<α1(22)

having the initial conditions

c(x,0)=sin(x).(23)

Exerting LT operator on Eq. (22) and by using Eq. (23), we get the following result

L[c(x,t)]1ssin(x)1sαLwcx+k2cx2=0.(24)

We represent the nonlinear operator given as follows

N[Ψ(x,t;q)]=L[Ψ(x,t;q)]1ssin(x)1sαLwΨ(x,t;q)x+k2Ψ(x,t;q)x2,(25)

and thus

Rm(cm1)=L(cm1)(1kmn)1ssin(x)1sαLwcm1x+k2cm1x2.(26)

The deformation equation of mth-order is represented in the following manner

L[cm(x,t)kmcm1(x,t)]=Rm(cm1).(27)

By using the inverse LT operator, we get

cm(x,t)=kmcm1(x,t)+L1[Rm(cm1)].(28)

Now on putting m = 1, 2, 3,… in Eq. (28) and solving it, we get the following iterates

c0(x,t)=sin(x),c1(x,t)=(ksin(x)+wcos(x))tαΓ(α+1),c2(x,t)=(+n)(ksin(x)+wcos(x))tαΓ(α+1)+2((k2w2)sin(x)+2kwcos(x))t2αΓ(2α+1),c3(x,t)=(+n)2(ksin(x)+wcos(x))tαΓ(α+1)+22(+n)((k2w2)sin(x)+2kwcos(x))t2αΓ(2α+1)3((k33kw2)sin(x)+(3k2ww3)cos(x))t3αΓ(3α+1),(29)

In the similar way, the remaining values of cm(x, t) for m > 3 can be attained and the obtained series solution is represented in the following equation

c(x,t)=m=0cm(x,t)1nm,(30)
c(x,t)=sin(x)+n(ksin(x)+wcos(x))tαΓ(α+1)+(+n)n2(ksin(x)+wcos(x))tαΓ(α+1)+2n2((k2w2)sin(x)+2kwcos(x))t2αΓ(2α+1)+(+n)2n3(ksin(x)+wcos(x))tαΓ(α+1)+22(+n)n3((k2w2)sin(x)+2kwcos(x)t2αΓ(2α+1)+3n3((k33kw2)sin(x)+(3k2ww3)cos(x))t3αΓ(3α+1)+(31)

If we set = –1 and n = 1 in (31), then we arrive at the results obtained by using HPM, DTM, RDTM, HPTM, LDM and ADM. The advantages of q-HATM over HAM, HPM, DTM, RDTM, HPTM, LDM and ADM is that q-HATM contains two parameters namely asymptotic parameter n and auxiliary parameter therefore we can easily settle and restrict the region of convergence of series solution derived with the aid of q-HATM by choosing suitable values of and n in a large domain.

Fig. 1 represents the behavior of the fourth order approximate q-FHATM surface solution of Eq. (22) verses x and time t. In Fig. 2 comparisons are made with Brownian motion i.e. α = 0.9, 0.8, 0.7 to standard motion i.e. α = 1 and show the continuity of fractional order derivatives for Eq. (22). Figs. 3(a)-(b) present the -curves. From Figs. 3(a)-3b) we can see that the value of is selected corresponding to n from the convergence region according to the -curve. The -curves contain a horizontal line segment that indicates the bounded range of which gives the guarantee of the convergence for Eq. (30).

Fig. 1 Approximate solution c for Eq. (22) at k = w = 0.8 and at (ℏ, n, α) = (–1,1,1).
Fig. 1

Approximate solution c for Eq. (22) at k = w = 0.8 and at (, n, α) = (–1,1,1).

Fig. 2 Fourth order approximation q-FHATM solution c verses time t for Eq. (22) at x = 0.5, k = w = 0.8 and different values of α.
Fig. 2

Fourth order approximation q-FHATM solution c verses time t for Eq. (22) at x = 0.5, k = w = 0.8 and different values of α.

Fig. 3 ℏ-curves for fourth order approximation q-FHATM solution of Eq. (22) for different value of α; (a) when n = 1, (b) or n = 5.
Fig. 3

-curves for fourth order approximation q-FHATM solution of Eq. (22) for different value of α; (a) when n = 1, (b) or n = 5.

Example 2

Now, we examine the nonhomogeneous space-fractional advection-dispersion equation given as follows

2βcx2βcx=ct+(22t2x),t>0,0<β1,(32)

having the boundary and initial conditions

c(0,t)=t2,cx(0,t)=0,c(x,0)=x2.(33)

Employing Laplace transform on Eq. (32) and using Eq. (33), we get

L[c(x,t)]1st22s2β+1+2s2β+1t+2s2β+21s2βLcx+ct=0.(34)

We construct the nonlinear operator in the following way

N[Ψ(x,t;q)]=L[Ψ(x,t;q)]t2s2s2β+1+2ts2β+1+2s2β+21s2βL[Ψ(x,t;q)x+Ψ(x,t;q)t],(35)

and thus

R(cm1)=L(cm1)1kmnt2s+2s2β+12s2β+1t2s2β+21s2βL[cm1x+cm1t].(36)

The deformation equation of mth-order is represented by

L[cm(x,t)kmcm1(x,t)]=Rm(cm1).(37)

By using the inverse LT operator on Eq. (37), we obtain

cm(x,t)=kmcm1(x,t)+L1[Rm(cm1)].(38)

For m = 1, 2, 3 … on solving Eq. (38), we have

c0(x,t)=t2+(22t)x2βΓ(2β+1)2x2β+1Γ(2β+2),c1(x,t)=2tx2βΓ(2β+1)+2x4βΓ(4β+1)(22t)x4β1Γ(4β)+2x4βΓ(4β+1),(39)

In the similar way, the remaining values of cm(x, t) for m > 1 can be gained and the q-FHATM solution in series form is obtained as

c(x,t)=m=0cm(x,t)1nm.(40)

If we put = –1 and n = 1 in (40), then we arrive at the results obtained by HPM, DTM, RDTM, HPTM, LDM and ADM. The advantages of q-HATM over HAM, HPM, DTM, RDTM, HPTM, LDM and ADM is that q-FHATM contains two parameters namely asymptotic parameter n and auxiliary parameter therefore we can easily settle and restrict the region of convergence of series solution derived with the aid of q-FHATM by choosing suitable values of and n in a large domain. When we put β = 1, = –1 and n = 1 in Eq. (40) then it converges to very fast to the exact solution c(x, t) = t2 + x2. The numerical results for HAM (q-FHATM, n = 1) are shown by Fig. 4(a)-(c) and it can be observed that c(x, t) increases with increase in both the variables x and t. On computation of the further components of c(x, t) it is verified that the accuracy and efficiency of the proposed technique can be dramatically improved when the q-FHATM is used and converge to the absolute error 0. Fig. 5 shows that the Brownian motion also a continuous and increasing function of space x at t = 0.5. Figs. 6(a)-(b) represent the -curves. The horizontal line segment in the -curves denotes the valid range of which gives guarantee for the convergence of series (40).

Fig. 4 The surfaces show solution c(x, t) for Eq. (32) at ℏ = –1, n = 1 and β = 1: (a) Exact solution; (b) 3rd order q-FHATM approximate solution; (c) 3rd order absolute error.
Fig. 4

The surfaces show solution c(x, t) for Eq. (32) at = –1, n = 1 and β = 1: (a) Exact solution; (b) 3rd order q-FHATM approximate solution; (c) 3rd order absolute error.

Fig. 5 3rd order approximation HAM (q-FHATM, n = 1) solution c(x, t) verses space x for Eq. (40) at t = 0.5, ℏ = –1 with different values of β.
Fig. 5

3rd order approximation HAM (q-FHATM, n = 1) solution c(x, t) verses space x for Eq. (40) at t = 0.5, = –1 with different values of β.

Fig. 6 ℏ-curves at x = 0.02, t = 0.5 and β = 1; (a) for n = 1, (b) for n = 200.
Fig. 6

-curves at x = 0.02, t = 0.5 and β = 1; (a) for n = 1, (b) for n = 200.

Example 3

Finally, consider the following time FADE subject to the initial condition is

αctα=k2cx2cx,0<α1,t>0.(41)

having the in itial condition

c(x,0)=ex.(42)

Solving the above equations in the similar way, we get the various components as follows

c0(x,t)=ex,c1(x,t)=(1+k)tαΓ(α+1)x,c2(x,t)=(+n)(1+k)tαΓ(α+1)ex+2(1+k)2t2αΓ(2α+1)ex,c3(x,t)=(+n)2(1+k)tαΓ(α+1)ex+22(+n)(1+k)2t2αΓ(2α+1)ex3(1+k)3t3αΓ(3α+1)ex,(43)

In the similar way, the remaining values of cm(x, t) for m > 3 can be attained and the series solution is obtained as follow

c(x,t)=m=0cm(x,t)1nm.(44)

Eq. (44) represents the family of series solution of Eq. (41).

If we select = –1 and n = 1 in (44), then we arrive at the results obtained with the help of HPM, DTM, RDTM, HPTM, LDM and ADM. The advantages of q-FHATM over HAM, HPM, DTM, RDTM, HPTM, LDM and ADM is that q-FHATM contains two parameters namely asymptotic parameter n and auxiliary parameter , therefore we can easily settle and restrict the region of convergence of series solution derived with the aid of q-FHATM by choosing suitable values of and n in a large domain.

If we select = –1 and n = 1, we get

c(x,t)=limNm=0Ncm(x,t)=exlimNr=0N(1+k)rΓ(rα+1)trα=exEα((1+k)tα),(45)

where Eα((1 + k)tα) is the well known Mittag-Leffler function [41].

Fig. 7 presents the surface of the q-FHATM solution. In Fig. 8, q-FHATM solution is presented for different values of different values of and n. Figs. 9(a)-(d) show the -curves. Table 1 presents the absolute converge range for different values of n. From Figs.9(a)-(d), we can see that the valid range of convergence increases with increasing the value of n.

Fig. 7 q-FHATM solution c(x, t) verses x and time t at k = 0.03 for Eq. (43) at (ℏ, n, α) = (−1,1,1).
Fig. 7

q-FHATM solution c(x, t) verses x and time t at k = 0.03 for Eq. (43) at (, n, α) = (−1,1,1).

Fig. 8 q-FHATM solution c(x,t) for Eq. (43) when k = 0.03, x = 0.5 , α = 1 for different values of ℏ and n.
Fig. 8

q-FHATM solution c(x,t) for Eq. (43) when k = 0.03, x = 0.5 , α = 1 for different values of and n.

Fig. 9 ℏ-curves for fourth order approximation q-FHATM solution of Eq. (43) at x = 0.5, t = 0.02 and k = 0.03, for (a) n = 1, (b) n = 5, (c) n = 100, (d) n = 110.
Fig. 9

-curves for fourth order approximation q-FHATM solution of Eq. (43) at x = 0.5, t = 0.02 and k = 0.03, for (a) n = 1, (b) n = 5, (c) n = 100, (d) n = 110.

Table 1

The fourth order absolute converge range of Eq. (44) decided from -curves at x = 0.5, t = 0.02, α =1 and k = 0.03.

nRange of
2–2.4 < < –1.68
5–6.5 ≤ < –3.8
8–9.9 < < –6.2
10–12 ≤ < –8
20–24 < ≤ – 17
50–60 < ≤ – 40.01
80–98 ≤ < –62
100–120 ≤ < –82 [Fig. 9(c)]
110–132 ≤ < –90 [Fig. 9(d)]

5 Explanation of -curves

The -curve and n-curve describe the q-FHATM series solution of space- and time- fractional advection-dispersion problems with all possible acceptable convergence range of corresponding to n and the central point of -curves interval i.e. = –n is a suitable choice, at this point the numerical solution convergences to series solution. Figs. 3(a)-(b) and Figs. 9(a)-(b) show that convergence range of decreases when α converge from their standard motion (α = 1) to Brownian motion (α = 0.9, 0.8) for STFADE’s. We have analyzed that convergence range increase/decrease with increase/decrease of arbitrary selected auxiliary parameter n(n ≥ 1) and -curve seem to the same value of q-FHATM solution c(x, t) for same value of α with different kind of n.

6 Conclusions

In this article, q-FHATM is effectively and successfully used to obtain a family of series solution for the STFADE’s by just utilizing the initial condition. Basic difference q-FHATM to HAM in their solution procedure is that HAM have the limitation for embedding parameter i.e. q = 1 but in q-FHATM, q is defined more general i.e. q = 12 , n ≥ 1. The most important advantages of q-FHATM over HAM, HPM, DTM, RDTM, HPTM, LDM and ADM is that q-FHATM contains two parameters namely asymptotic parameter n and auxiliary parameter , therefore we can easily settle and restrict the region of convergence of series solution derived with the aid of q-FHATM by choosing suitable values of and n in a large domain. To control and insure the convergence of series for generalized approach, we have noticed that the q-FHATM provides many more option. Hence, we can conclude that the suggested algorithm is very useful for examining the STFADE’s and similar kind of problems.

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Received: 2018-01-26
Revised: 2018-03-13
Accepted: 2018-04-07
Published Online: 2018-06-04
Published in Print: 2019-01-28

© 2019 J. Singh et al., published by De Gruyter.

This work is licensed under the Creative Commons Attribution 4.0 Public License.

Artikel in diesem Heft

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  2. Concentrating solar power tower technology: present status and outlook
  3. Control of separately excited DC motor with series multi-cells chopper using PI - Petri nets controller
  4. Effect of boundary roughness on nonlinear saturation of Rayleigh-Taylor instability in couple-stress fluid
  5. Effect of Heterogeneity on Imbibition Phenomena in Fluid Flow through Porous Media with Different Porous Materials
  6. Electro-osmotic flow of a third-grade fluid past a channel having stretching walls
  7. Heat transfer effect on MHD flow of a micropolar fluid through porous medium with uniform heat source and radiation
  8. Local convergence for an eighth order method for solving equations and systems of equations
  9. Numerical techniques for behavior of incompressible flow in steady two-dimensional motion due to a linearly stretching of porous sheet based on radial basis functions
  10. Influence of Non-linear Boussinesq Approximation on Natural Convective Flow of a Power-Law Fluid along an Inclined Plate under Convective Thermal Boundary Condition
  11. A reliable analytical approach for a fractional model of advection-dispersion equation
  12. Mass transfer around a slender drop in a nonlinear extensional flow
  13. Hydromagnetic Flow of Heat and Mass Transfer in a Nano Williamson Fluid Past a Vertical Plate With Thermal and Momentum Slip Effects: Numerical Study
  14. A Study on Convective-Radial Fins with Temperature-dependent Thermal Conductivity and Internal Heat Generation
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  29. Magnetohydrodynamic(MHD) Boundary Layer Flow of Eyring-Powell Nanofluid Past Stretching Cylinder With Cattaneo-Christov Heat Flux Model
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  60. Influence of Joule Heating and Non-Linear Radiation on MHD 3D Dissipating Flow of Casson Nanofluid past a Non-Linear Stretching Sheet
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https://doi.org/10.1515/nleng-2018-0027
Schlagwörter für diesen Artikel
Fractional advection-dispersion problem; Laplace transform method; q-fractional homotopy analysis transform technique; Mittage-Leffler function
Creative Commons
BY 4.0

Artikel in diesem Heft

  1. Chebyshev Operational Matrix Method for Lane-Emden Problem
  2. Concentrating solar power tower technology: present status and outlook
  3. Control of separately excited DC motor with series multi-cells chopper using PI - Petri nets controller
  4. Effect of boundary roughness on nonlinear saturation of Rayleigh-Taylor instability in couple-stress fluid
  5. Effect of Heterogeneity on Imbibition Phenomena in Fluid Flow through Porous Media with Different Porous Materials
  6. Electro-osmotic flow of a third-grade fluid past a channel having stretching walls
  7. Heat transfer effect on MHD flow of a micropolar fluid through porous medium with uniform heat source and radiation
  8. Local convergence for an eighth order method for solving equations and systems of equations
  9. Numerical techniques for behavior of incompressible flow in steady two-dimensional motion due to a linearly stretching of porous sheet based on radial basis functions
  10. Influence of Non-linear Boussinesq Approximation on Natural Convective Flow of a Power-Law Fluid along an Inclined Plate under Convective Thermal Boundary Condition
  11. A reliable analytical approach for a fractional model of advection-dispersion equation
  12. Mass transfer around a slender drop in a nonlinear extensional flow
  13. Hydromagnetic Flow of Heat and Mass Transfer in a Nano Williamson Fluid Past a Vertical Plate With Thermal and Momentum Slip Effects: Numerical Study
  14. A Study on Convective-Radial Fins with Temperature-dependent Thermal Conductivity and Internal Heat Generation
  15. An effective technique for the conformable space-time fractional EW and modified EW equations
  16. Fractional variational iteration method for solving time-fractional Newell-Whitehead-Segel equation
  17. New exact and numerical solutions for the effect of suction or injection on flow of nanofluids past a stretching sheet
  18. Numerical investigation of MHD stagnation-point flow and heat transfer of sodium alginate non-Newtonian nanofluid
  19. A New Finance Chaotic System, its Electronic Circuit Realization, Passivity based Synchronization and an Application to Voice Encryption
  20. Analysis of Heat Transfer and Lifting Force in a Ferro-Nanofluid Based Porous Inclined Slider Bearing with Slip Conditions
  21. Application of QLM-Rational Legendre collocation method towards Eyring-Powell fluid model
  22. Hyperbolic rational solutions to a variety of conformable fractional Boussinesq-Like equations
  23. MHD nonaligned stagnation point flow of second grade fluid towards a porous rotating disk
  24. Nonlinear Dynamic Response of an Axially Functionally Graded (AFG) Beam Resting on Nonlinear Elastic Foundation Subjected to Moving Load
  25. Swirling flow of couple stress fluid due to a rotating disk
  26. MHD stagnation point slip flow due to a non-linearly moving surface with effect of non-uniform heat source
  27. Effect of aligned magnetic field on Casson fluid flow over a stretched surface of non-uniform thickness
  28. Nonhomogeneous porosity and thermal diffusivity effects on stability and instability of double-diffusive convection in a porous medium layer: Brinkman Model
  29. Magnetohydrodynamic(MHD) Boundary Layer Flow of Eyring-Powell Nanofluid Past Stretching Cylinder With Cattaneo-Christov Heat Flux Model
  30. On the connection coefficients and recurrence relations arising from expansions in series of modified generalized Laguerre polynomials: Applications on a semi-infinite domain
  31. An adaptive mesh method for time dependent singularly perturbed differential-difference equations
  32. On stretched magnetic flow of Carreau nanofluid with slip effects and nonlinear thermal radiation
  33. Rational exponential solutions of conformable space-time fractional equal-width equations
  34. Simultaneous impacts of Joule heating and variable heat source/sink on MHD 3D flow of Carreau-nanoliquids with temperature dependent viscosity
  35. Effect of magnetic field on imbibition phenomenon in fluid flow through fractured porous media with different porous material
  36. Impact of ohmic heating on MHD mixed convection flow of Casson fluid by considering Cross diffusion effect
  37. Mathematical Modelling Comparison of a Reciprocating, a Szorenyi Rotary, and a Wankel Rotary Engine
  38. Surface roughness effect on thermohydrodynamic analysis of journal bearings lubricated with couple stress fluids
  39. Convective conditions and dissipation on Tangent Hyperbolic fluid over a chemically heating exponentially porous sheet
  40. Unsteady Carreau-Casson fluids over a radiated shrinking sheet in a suspension of dust and graphene nanoparticles with non-Fourier heat flux
  41. An efficient numerical algorithm for solving system of Lane–Emden type equations arising in engineering
  42. New numerical method based on Generalized Bessel function to solve nonlinear Abel fractional differential equation of the first kind
  43. Numerical Study of Viscoelastic Micropolar Heat Transfer from a Vertical Cone for Thermal Polymer Coating
  44. Analysis of Bifurcation and Chaos of the Size-dependent Micro–plate Considering Damage
  45. Non-Similar Comutational Solutions for Double-Diffusive MHD Transport Phenomena for Non-Newtnian Nanofluid From a Horizontal Circular Cylinder
  46. Mathematical model on distributed denial of service attack through Internet of things in a network
  47. Postbuckling behavior of functionally graded CNT-reinforced nanocomposite plate with interphase effect
  48. Study of Weakly nonlinear Mass transport in Newtonian Fluid with Applied Magnetic Field under Concentration/Gravity modulation
  49. MHD slip flow of chemically reacting UCM fluid through a dilating channel with heat source/sink
  50. A Study on Non-Newtonian Transport Phenomena in Mhd Fluid Flow From a Vertical Cone With Navier Slip and Convective Heating
  51. Penetrative convection in a fluid saturated Darcy-Brinkman porous media with LTNE via internal heat source
  52. Traveling wave solutions for (3+1) dimensional conformable fractional Zakharov-Kuznetsov equation with power law nonlinearity
  53. Semitrailer Steering Control for Improved Articulated Vehicle Manoeuvrability and Stability
  54. Thermomechanical nonlinear stability of pressure-loaded CNT-reinforced composite doubly curved panels resting on elastic foundations
  55. Combination synchronization of fractional order n-chaotic systems using active backstepping design
  56. Vision-Based CubeSat Closed-Loop Formation Control in Close Proximities
  57. Effect of endoscope on the peristaltic transport of a couple stress fluid with heat transfer: Application to biomedicine
  58. Unsteady MHD Non-Newtonian Heat Transfer Nanofluids with Entropy Generation Analysis
  59. Mathematical Modelling of Hydromagnetic Casson non-Newtonian Nanofluid Convection Slip Flow from an Isothermal Sphere
  60. Influence of Joule Heating and Non-Linear Radiation on MHD 3D Dissipating Flow of Casson Nanofluid past a Non-Linear Stretching Sheet
  61. Radiative Flow of Third Grade Non-Newtonian Fluid From A Horizontal Circular Cylinder
  62. Application of Bessel functions and Jacobian free Newton method to solve time-fractional Burger equation
  63. A reliable algorithm for time-fractional Navier-Stokes equations via Laplace transform
  64. A multiple-step adaptive pseudospectral method for solving multi-order fractional differential equations
  65. A reliable numerical algorithm for a fractional model of Fitzhugh-Nagumo equation arising in the transmission of nerve impulses
  66. The expa function method and the conformable time-fractional KdV equations
  67. Comment on the paper: “Thermal radiation and chemical reaction effects on boundary layer slip flow and melting heat transfer of nanofluid induced by a nonlinear stretching sheet, M.R. Krishnamurthy, B.J. Gireesha, B.C. Prasannakumara, and Rama Subba Reddy Gorla, Nonlinear Engineering 2016, 5(3), 147-159”
  68. Three-Dimensional Boundary layer Flow and Heat Transfer of a Fluid Particle Suspension over a Stretching Sheet Embedded in a Porous Medium
  69. MHD three dimensional flow of Oldroyd-B nanofluid over a bidirectional stretching sheet: DTM-Padé Solution
  70. MHD Convection Fluid and Heat Transfer in an Inclined Micro-Porous-Channel
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