We show that a nonlinear equation that represents third-order approximation of long wavelength, small amplitude waves of inviscid and incompressible fluids is integrable for a particular choice of its parameters, since in this case it is equivalent with an integrable equation which has recently appeared in the literature. We also discuss the integrability of both second- and third-order approximations of additional cases.

1. Introduction

The one-dimensional motion of solitary waves of inviscid and incompressible fluids has been the subject of research for more than a century [1]. Probably, one of the most important results in the above study was the derivation of the famous Korteweg-de Vries (KdV) equation [2]

(1.1)

At first, the equation was difficult to be examined due to the nonlinearity. The first important step was made with the numerical discovery of soliton solutions by Zabusky and Kruskal [3]. Soon thereafter great progress was made by the discovery of the Lax Pair representation [4] and the Inverse Scattering Transform [5]. The laters results led to a new notion of integrability. More specifically, according to this notion, a partial differential equation is said to be “completely integrable” if it is linearizable through a Lax Pair; thus, it is solvable via the Inverse Scattering Transform (see, e.g., [6]).

Equation (1.1) represents a first-order approximation in the study of long wavelength, small amplitude waves of inviscid and incompressible fluids. Allowing the appearance of higher-order terms in α and β, one can obtain more complicated equations. Two such equations, including second- and third-order terms, were proposed in [7, 8] and have, respectively, the forms

(1.2)

(1.3)

Equation (1.2) was first examined both analytically and numerically in [9]. The violation of the Painlevé property in many cases, together with a numerical study of the reduction u = u(x) in the complex x-plane, gave strong indications that, in general, this equation is not integrable. Consequently, (1.2) was examined in [10, 11] and it was found that it possesses solitary wave solutions, which, for small values of the parameters α and β, behave like solitons. New wave solutions of both (1.2) and (1.3) were also examined numerically in [12] and were also found to behave like solitons.

Equation (1.2) was further examined in [13–20], while (1.3) was examined in [18, 21, 22]. Although an enormous amount of new solutions was presented, no progress has been made regarding the integrability of these equations.

In this paper we show that, for arbitrary ρ₁ and

(1.4)

equation (1.3) is equivalent to an integrable equation recently proposed by Qiao and Liu [23]. We, thus, reveal an integrable case of (1.3) itself. We also discuss the existence of additional integrable cases for both (1.2) and (1.3).

2. An Integrable Case of (1.3)

Recently, Qiao and Liu [23] proposed a new integrable equation, namely,

(2.1)

The integrability follows directly from the fact that the equation admits a Lax Pair; thus, as mentioned above, is solvable by the Inverse Scattering Transform.

It is quite easy to prove that (2.1) is actually a subcase of (1.3). More specifically, we first set

(2.2)

thus, (2.1) becomes

(2.3)

We then set

(2.4)

where a_i are constants; substitute in (1.3), divide by a₁, and write x instead of X. We thus obtain

(2.5)

Clearly, (2.3) and (2.5) are equivalent if the following terms vanish:

(2.6)

Since αβa₁a₃ ≠ 0, relations A₇ = 0, A₂ = 0, and A₆ = 0 imply, respectively, that

(2.7)

while relations A₃ = 0 and A₅ = 0 imply that

(2.8)

Then, relations A₄ = 0, A₁ = 0, A₉ = 0, and A₁₀ = 0 yield, respectively,

(2.9)

Finally,

(2.10)

We, thus, conclude with relations (1.4), while ρ₁ remains arbitrary.

3. Discussion

In [9] it was shown that (1.2) does not pass the classical Painlevé test [24, 25] for any combination of the ρ_i parameters, except of course for the cases ρ₁ = ρ₂ = ρ₃ = 0 and ρ₂ = ρ₃ = 0 in which it reduces to KdV and modified KdV, respectively. However, as also stated in [9], there are infinitely many cases for which the equation has only algebraic singularities, that is, it admits the so-called weak-Painlevé property [26]. Although this property does not constitute a strong indication for integrability, there are still many integrable equations admitting only algebraic singularities (see, e.g., [27]).

On the other hand, at least to our knowledge, no results regarding integrable cases of (1.3) have appeared in the bibliography before. Equation (1.3) is highly nonlinear and most probably it is not integrable in general. However, as shown in the previous section, there is at least one nontrivial combination of the ρ_i parameters, for which it is completely integrable.

Based on the above statements, we believe that it would be interesting to study whether there are any integrable cases for (1.2) or any additional integrable cases for (1.3). We hope to present results in this direction in a future publication.

References

1 Whitham G. B., Linear and Nonlinear Waves, 1974, John Wiley & Sons, New York, NY, USA, Pure and Applied Mathematics, MR0483954, ZBL0373.76001.
Web of Science® Google Scholar
2 Korteweg D. J. and de Vries G., On the change of form of long waves advancing in a rectangular canal, and on a new type of long stationary Waves, Philosophical Magazine. (1895) 39, 422–443.
10.1080/14786449508620739
Google Scholar
3 Zabusky N. J. and Kruskal M. D., Interaction of “solitons” in a collisionless plasma and the recurrence of initial states, Physical Review Letters. (1965) 15, no. 6, 240–243, 2-s2.0-33846361348, https://doi.org/10.1103/PhysRevLett.15.240.
10.1103/PhysRevLett.15.240
Web of Science® Google Scholar
4 Lax P. D., Integrals of nonlinear equations of evolution and solitary waves, Communications on Pure and Applied Mathematics. (1968) 21, no. 5, 467–490, MR0235310, https://doi.org/10.1002/cpa.3160210503, ZBL0162.41103.
10.1002/cpa.3160210503
Web of Science® Google Scholar
5 Gardner C. S., Greene J. M., Kruskal M. D., and Miura R. M., Method for solving the Korteweg—de Vries equation, Physical Review Letters. (1967) 19, no. 19, 1095–1097, 2-s2.0-36049057587, https://doi.org/10.1103/PhysRevLett.19.1095.
10.1103/PhysRevLett.19.1095
CAS Web of Science® Google Scholar
6 Ablowitz M. J. and Segur H., Solitons and the Inverse Scattering Transform, 1981, 4, SIAM, Philadelphia, Pa, USA, SIAM Studies in Applied Mathematics, MR642018.
10.1137/1.9781611970883
Google Scholar
7 Fokas A. S., On a class of physically important integrable equations, Physica D. (1995) 87, no. 1–4, 145–150, https://doi.org/10.1016/0167-2789(95)00133-O, MR1361680.
10.1016/0167-2789(95)00133-O
Web of Science® Google Scholar
8 Fokas A. S. and Liu Q. M., Asymptotic integrability of water waves, Physical Review Letters. (1996) 77, no. 12, 2347–2351, https://doi.org/10.1103/PhysRevLett.77.2347, MR1406987, ZBL0982.76511.
10.1103/PhysRevLett.77.2347
CAS PubMed Web of Science® Google Scholar
9 Marinakis V. and Bountis T. C., D. B. Duncan and J. C. Eilbeck, On the integrability of a new class of water wave equations, Proceedings of the Conference on Nonlinear Coherent Structures in Physics and Biology, July 1995, Edinburgh, UK, Heriot-Watt University.
Google Scholar
10 Marinakis V. and Bountis T. C., Special solutions of a new class of water wave equations, Communications in Applied Analysis. (2000) 4, no. 3, 433–445, MR1772579, ZBL1084.76511.
Google Scholar
11 Tzirtzilakis E., Xenos M., Marinakis V., and Bountis T. C., Interactions and stability of solitary waves in shallow water, Chaos, Solitons & Fractals. (2002) 14, no. 1, 87–95, https://doi.org/10.1016/S0960-0779(01)00211-9, MR1891401, ZBL1068.76011.
10.1016/S0960-0779(01)00211-9
Web of Science® Google Scholar
12 Tzirtzilakis E., Marinakis V., Apokis C., and Bountis T., Soliton-like solutions of higher order wave equations of the Korteweg—de Vries type, Journal of Mathematical Physics. (2002) 43, no. 12, 6151–6165, https://doi.org/10.1063/1.1514387, MR1939637, ZBL1060.35127.
10.1063/1.1514387
Web of Science® Google Scholar
13 Khuri S. A., Soliton and periodic solutions for higher order wave equations of KdV type. I, Chaos, Solitons & Fractals. (2005) 26, no. 1, 25–32, https://doi.org/10.1016/j.chaos.2004.12.027, MR2144545, ZBL1070.35062.
10.1016/j.chaos.2004.12.027
Web of Science® Google Scholar
14 Hong W.-P., [email protected], Dynamics of solitary-waves in the higher order Korteweg—de Vries equation type (I), Zeitschrift für Naturforschung. (2005) 60, no. 11-12, 757–767, 2-s2.0-11144322962.
10.1515/zna-2005-11-1201
CAS Google Scholar
15 Li J., Rui W., Long Y., and He B., Travelling wave solutions for higher-order wave equations of KdV type. III, Mathematical Biosciences and Engineering. (2006) 3, no. 1, 125–135, MR2192129, ZBL1136.35449.
10.3934/mbe.2006.3.125
Web of Science® Google Scholar
16 Long Y., Li J., Rui W., and He B., Traveling wave solutions for a second order wave equation of KdV type, Applied Mathematics and Mechanics. (2007) 28, no. 11, 1455–1465, https://doi.org/10.1007/s10483-007-1105-y, MR2435732.
10.1007/s10483-007-1105-y
Google Scholar
17 Marinakis V., New solutions of a higher order wave equation of the KdV type, Journal of Nonlinear Mathematical Physics. (2007) 14, no. 4, 519–525, https://doi.org/10.2991/jnmp.2007.14.4.2, MR2358205, ZBL1170.35518.
10.2991/jnmp.2007.14.4.2
Web of Science® Google Scholar
18 Marinakis V., [email protected], New solitary wave solutions in higher-order wave equations of the Korteweg—de Vries type, Zeitschrift für Naturforschung. (2007) 62, no. 5-6, 227–230, 2-s2.0-0037155041.
10.1515/zna-2007-5-601
CAS Google Scholar
19 Li J., Exact explicit peakon and periodic cusp wave solutions for several nonlinear wave equations, Journal of Dynamics and Differential Equations. (2008) 20, no. 4, 909–922, https://doi.org/10.1007/s10884-008-9114-5, MR2448218, ZBL1178.34002.
10.1007/s10884-008-9114-5
Web of Science® Google Scholar
20 Rui W., Long Y., and He B., Some new travelling wave solutions with singular or nonsingular character for the higher order wave equation of KdV type (III), Nonlinear Analysis: Theory, Methods & Applications. (2009) 70, no. 11, 3816–3828, https://doi.org/10.1016/j.na.2008.07.040, MR2515301, ZBL1167.34006.
10.1016/j.na.2008.07.040
Web of Science® Google Scholar
21 Li J., Wu J., and Zhu H., Traveling waves for an integrable higher order KdV type wave equations, International Journal of Bifurcation and Chaos. (2006) 16, no. 8, 2235–2260, https://doi.org/10.1142/S0218127406016033, MR2266012.
10.1142/S0218127406016033
Web of Science® Google Scholar
22 Li J., Dynamical understanding of loop soliton solution for several nonlinear wave equations, Journal Science in China Series A. (2007) 50, no. 6, 773–785, https://doi.org/10.1007/s11425-007-0039-y, MR2353061, ZBL1139.35076.
10.1007/s11425-007-0039-y
Google Scholar
23 Qiao Z. and Liu L., A new integrable equation with no smooth solitons, Chaos, Solitons & Fractals. (2009) 41, no. 2, 587–593, https://doi.org/10.1016/j.chaos.2007.11.034, MR2535607.
10.1016/j.chaos.2007.11.034
Web of Science® Google Scholar
24 Weiss J., Tabor M., and Carnevale G., The Painlevé property for partial differential equations, Journal of Mathematical Physics. (1983) 24, no. 3, 522–526, https://doi.org/10.1063/1.525721, MR692140, ZBL0531.35069.
10.1063/1.525721
Web of Science® Google Scholar
25 Weiss J., The Painlevé property for partial differential equations. II. Bäcklund transformation, Lax pairs, and the Schwarzian derivative, Journal of Mathematical Physics. (1983) 24, no. 6, 1405–1413, https://doi.org/10.1063/1.525875, MR708655, ZBL0531.35069.
10.1063/1.525875
Web of Science® Google Scholar
26 Ramani A., Dorizzi B., and Grammaticos B., Painlevé conjecture revisited, Physical Review Letters. (1982) 49, no. 21, 1539–1541, https://doi.org/10.1103/PhysRevLett.49.1539, MR682678.
10.1103/PhysRevLett.49.1539
Web of Science® Google Scholar
27 Gilson C. and Pickering A., Factorization and Painlevé analysis of a class of nonlinear third-order partial differential equations, Journal of Physics A. (1995) 28, no. 10, 2871–2888, MR1343881, https://doi.org/10.1088/0305-4470/28/10/017, ZBL0830.35127.
10.1088/0305-4470/28/10/017
Web of Science® Google Scholar

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Higher-Order Equations of the KdV Type are Integrable

Abstract

1. Introduction

2. An Integrable Case of (1.3)

3. Discussion

References

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Higher-Order Equations of the KdV Type are Integrable

Abstract

1. Introduction

2. An Integrable Case of (1.3)

3. Discussion

References

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