Solitary Wave Solutions of Conformable Time Fractional Equations Using Modified Simplest Equation Method

Razzaq, Waseem; Habib, Mustafa; Nadeem, Muhammad; Zafar, Asim; Khan, Ilyas; Mwanakatwea, Patrick Kandege

doi:https://doi.org/10.1155/2022/8705388

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Volume 2022 | Article ID 8705388 | https://doi.org/10.1155/2022/8705388

Solitary Wave Solutions of Conformable Time Fractional Equations Using Modified Simplest Equation Method

Waseem Razzaq,¹Mustafa Habib,²Muhammad Nadeem,³Asim Zafar,⁴Ilyas Khan,⁵and Patrick Kandege Mwanakatwea⁶

Academic Editor: C. Rajivganthi

Received01 Feb 2022

Revised02 Mar 2022

Accepted09 Mar 2022

Published22 Apr 2022

Abstract

This study presents a modified simplest equation method (MSEM) to investigate some real and exact solutions of conformable time fractional Benjamin-Bona-Mahony (BBM) equation and Chan-Hilliard (CH) equation. We use traveling wave transformation to obtain the results in the form of series solution. Some calculations are performed through Mathematica software to analyze the accuracy of this approach. Graphical representations are reported for more significant results at different fractional-order which demonstrates that this approach is very simple, adequate, and legitimate.

1. Introduction

Various applications of applied mathematics in the form of partial differential equations (PDEs) play important role with derivative and integral of arbitrary orders. Fractional differential equations (FDEs) are used for modeling in various fields of sciences such as physics, chemistry, mathematics, biology, engineering, fluid dynamics, and other physical phenomena [1–4]. So, they have gained much attention of many scholar. The exact/analytical solutions of these PDEs are ideal. Therefore, a lot of scholars have paid much attentions to acquire the solutions of these kinds of FDEs with the help of various numerical and analytical methods. Mainly, a wave transformation is used to transform the FDEs into a nonlinear ordinary differential equation, which leads for further exact solution. A lot of significant approaches have been generated and applied to search exact solutions in different research articles including Lie symmetry analysis method [5–8], the differential transform method [9], the iteration method [10, 11], the (G’/G)-expansion method [12], homotopy analysis method [13], Adomian decomposition method [14], homotopy perturbation method [15], the functional variable method [16], the first integral method [1], modified Kudryashov method [17], -expansion [18], and improved -expansion method [19]. Very recently, Wang presented a new idea on the fractal theory of nonlinear system to find the solitary wave solutions which show the promising results [20–22]. A full detail of conformable time fractional equations has been explained in [23, 24].

In this work, we will go over the conformable time fractional BBM and nonlinear space-time fractional CH equation. Many inquirer quaere the exact solutions of these equations by applying different approaches in the past [25–27]. Some recent developments in time fractional equations developments can be studied through He’s fractional derivative and the two-scale fractal derivative [28, 29]. We discussed some of their investigations here. They used fractional exp-function method to construct the exact solutions for the conformable time fractional Benjamin-Bona-Mahony equation and conformable time fractional Chan-Hilliard equation. The scheme of this paper is as follows: in Section 2, we will briefly discuss some basic properties of conformable fractional derivative. In Section 3, we present the description of simplest equation method. Two examples of conformable time fractional BBM and CH have been tested in Section 4 to verify this approach and conclusion is discussed in Section 5.

2. Conformable Fractional Derivative

In this part, we shortly explain the definition and properties of conformable fractional derivatives [30–33].

Definition: let be a function. Then, the conformable fractional derivative of for order is defined as

Assuming the conformable fractional derivative on regarding order , then we can say is -differentiable.

Properties: let and be -differentiable at a value , then the conformable fractional derivative has some useful properties as follows:(1), for all (2)(3), for all (4), where is constant(5)(6)If is differentiable, then

This definition also satisfies the chain rule as follows.

Let be an -differentiable function and . Then, the following rule is defined.

3. Description of the Modified Simplest Equation Method (MSEM)

Consider the following nonlinear PDE in the form time fractionalwhere is known as conformable fractional derivative and . (3) has independent variables and dependent variable , where

We will execute MSEM to provide particular results of (3). Over here, we summarize the fundamental points of MSEM.

Step 1. Employing the fractional traveling wave transform,where k, l are nonzero constants; we can rewrite (3) as the following nonlinear ODE:where

Step 2. Consider the solution of equation (6) in the following form:where are constants and , whereas conforms to some ordinary differential equations. Now, consider the Riccati equations such aswhere is an arbitrary constant and prime represents the differentiation according to . We can dissolve the solution of (8) in the following possible ways:
If , thenIf , thenIf , then

Step 3. After substituting equations (7) and (8) into (6), and setting all the coefficients of to zero, we can get the system of algebraic equations in terms of , which leads to a very simple solution.

Step 4. The obtained values of from Step 2 can be used in equation (5) to achieve the traveling wave solutions of equation (3).
Remarks. The results in equation (9) or (10) are referred to as the solitary wave solutions and the results in equation (13) or (14) are considered to be periodic function solutions, whereas the result in equation (18) is termed as rational function solution.

4. Applications of MSEM

In this section, MSEM is applied to compute the solitary wave solutions of conformable time fractional differential BBM and CH equation.

4.1. Example 1

Consider the conformable time fractional differential BBM equation:where is a parameter representing the order of the fractional time derivative. When , equation (19) is called classical Benjamin-Bona-Mahony equation. We used a new proposed simplest equation method and applied it on the conformable time fractional differential Benjamin-Bona-Mahony equation for obtaining the exact solutions.

By using the transformation,

Equation (19) can be reduced to the following nonlinear ODE:

Balancing in equation (22), then we drive .

Putting equation (22) into (21) and using some mathematical operations, we obtained an algebraic system. Solving this system for different value of results in the following.

Case 1. where . Therefore, we obtain the following solitary wave solution for the equation:where . Therefore, we obtain the following periodic function solution for the equation:If ,

Case 2. where . Therefore, we obtain the following solitary wave solution for the equation:Thus, we can obtain the following periodic function solution for the equation:If ,

4.2. Example 2

Let us consider the conformable time fractional CH equation

Applying the transformation,

Equation (38) is reduced to the following nonlinear ODE:

Through balancing the terms and , we select , then the nontrivial solution (40) reduces to

By setting the above solution in (40) and equating factors of each power of , we get nonlinear algebraic system, solving this system for different value of . Case 1:

If ,

Case 3. If ,If ,

5. Conclusion

By using simplest equation method, we have succeeded to find out the solitary wave and periodic and rational solutions of conformable nonlinear space-time fractional differential BBM and CH equations. These solutions have also been demonstrated through graph. Figures 1–3 show the solitary wave profile of for conformable time fractional differential BBM equation, whereas Figures 4 and 5 represent the solitary wave profile of for conformable time fractional differential CH equation. All the results are obtained with the help of traveling wave transformation. At the end, it is concluded that the simplest equation method suggests an innovative and powerful mathematical aid to deal with nonlinear partial differential equations of a wide class of nonlinear fractional-order of mathematical models in science and engineering. The performance of this method can also be used for fractal theory and microgravity space in our future research.

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Data Availability

All the data are available within the article.

Conflicts of Interest

The authors declare that they have no conflicts of interest in this article.

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Copyright © 2022 Waseem Razzaq et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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