In mathematics, the KuramotoâÂÂSivashinsky equation (also called the KS equation) is a partial differential equation used to model complex patterns and chaotic behavior in physical systems. It is one of the simplest PDEs known to exhibit chaos. The fourth-order equation was first derived in the late 1970s by Yoshiki Kuramoto and Gregory Sivashinsky to describe the instabilities of a laminar flame front. It has since been found to apply to other systems, such as the flow of a thin liquid film down an inclined plane and trapped-ion instability in plasmas.
The 1d version of the KuramotoâÂÂSivashinsky equation is
An alternate form is
obtained by differentiating with respect to and substituting . This is the form used in fluid dynamics applications.
The KuramotoâÂÂSivashinsky equation can also be generalized to higher dimensions. In spatially periodic domains, one possibility is
where is the Laplace operator, and is the biharmonic operator.
The Cauchy problem for the 1d KuramotoâÂÂSivashinsky equation is well-posed in the sense of HadamardâÂÂthat is, for given initial data , there exists a unique solution that depends continuously on the initial data.
The 1d KuramotoâÂÂSivashinsky equation possesses Galilean invarianceâÂÂthat is, if is a solution, then so is , where is an arbitrary constant. Physically, since is a velocity, this change of variable describes a transformation into a frame that is moving with constant relative velocity . On a periodic domain, the equation also has a reflection symmetry: if is a solution, then is also a solution.
Solutions of the KuramotoâÂÂSivashinsky equation possess rich dynamical characteristics. Considered on a periodic domain , the dynamics undergoes a series of bifurcations as the domain size is increased, culminating in the onset of chaotic behavior. Depending on the value of , solutions may include equilibria, relative equilibria, and traveling wavesâÂÂall of which typically become dynamically unstable as is increased. In particular, the transition to chaos occurs by a cascade of period-doubling bifurcations.
A third-order derivative term representing dispersion of wavenumbers are often encountered in many applications. The disperseively modified KuramotoâÂÂSivashinsky equation, which is often called as the Kawahara equation, is given by
where is real parameter. A fifth-order derivative term is also often included, which is the modified Kawahara equation and is given by
Three forms of the sixth-order KuramotoâÂÂSivashinsky equations are encountered in applications involving tricritical points, which are given by
in which the last equation is referred to as the Nikolaevsky equation, named after V. N. Nikolaevsky who introduced the equation in 1989, whereas the first two equations has been introduced by P. Rajamanickam and J. Daou in the context of transitions near tricritical points, i.e., change in the sign of the fourth derivative term with the plus sign approaching a KuramotoâÂÂSivashinsky type and the minus sign approaching a GinzburgâÂÂLandau type.
Applications of the KuramotoâÂÂSivashinsky equation extend beyond its original context of flame propagation and reactionâÂÂdiffusion systems. These additional applications include flows in pipes and at interfaces, plasmas, chemical reaction dynamics, and models of ion-sputtered surfaces.