Cubic NLW/NLKG: Difference between revisions

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(Introduced exact solutions of nonlinear wave equation without a mass term displaying massive dispersion law)
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The cubic nonlinear wave and Klein-Gordon equations have
The cubic nonlinear wave and Klein-Gordon equations have
been studied [[Cubic NLW/NLKG on R|on R]], [[Cubic NLW/NLKG on R2|on R^2]], and [[Cubic NLW/NLKG on R3|on R^3]].
been studied [[Cubic NLW/NLKG on R|on R]], [[Cubic NLW/NLKG on R2|on R^2]], and [[Cubic NLW/NLKG on R3|on R^3]].
This kind of equation displays a class of solutions with a peculiar dispersion law. To show explicitly this, let us consider the massless equation
<center><math>\Box\phi + \lambda\phi^3 = 0</math></center>
being <math>\lambda>0</math>. An exact solution of this equation is given by
<center><math>\phi(x) = \mu\left(\frac{2}{\lambda}\right)^{1\over 4}{\rm sn}(p\cdot x+\theta,i),</math></center>
being sn a Jacobi elliptic function and <math>\mu,\theta</math> two integration constants, when
<center><math>p^2=\mu^2\left(\frac{\lambda}{2}\right)^{1\over 2}.</math></center>
We see that we started with an equation without a mass term but the exact solution describes a wave with a dispersion relation proper to a massive solution. This can be seen as the superposition of an infinite number of massive linear waves through a Fourier series of the Jacobi function, that is
<center><math>\phi(t,0)=\sum_{n=0}^\infty(-1)^n\frac{2\pi}{K(i)}\frac{e^{\left(n+{1\over 2}\right)\pi}}{1+e^{-(2n+1)\pi}}\sin\left((2n+1)\frac{\pi}{2K(i)}\left(\frac{\lambda}{2}\right)^{1\over 4}\mu t\right)</math></center>
being <math>K(i)</math> an elliptic integral. We recognize the spectrum
<center><math>m_n = (2n+1)\frac{\pi}{2K(i)}\left(\frac{\lambda}{2}\right)^{1\over 4}\mu.</math></center>
Via the mapping theorem [[FraE2007]] this is also an exact solution of [[Yang-Mills equations]] with the substitution <math>\lambda\rightarrow Ng^2</math> for a SU(N) Lie group.


[[Category:Wave]]
[[Category:Wave]]
[[Category:Equations]]
[[Category:Equations]]

Revision as of 09:25, 14 November 2008


The cubic nonlinear wave and Klein-Gordon equations have been studied on R, on R^2, and on R^3.

This kind of equation displays a class of solutions with a peculiar dispersion law. To show explicitly this, let us consider the massless equation

being . An exact solution of this equation is given by

being sn a Jacobi elliptic function and two integration constants, when

We see that we started with an equation without a mass term but the exact solution describes a wave with a dispersion relation proper to a massive solution. This can be seen as the superposition of an infinite number of massive linear waves through a Fourier series of the Jacobi function, that is

being an elliptic integral. We recognize the spectrum

Via the mapping theorem FraE2007 this is also an exact solution of Yang-Mills equations with the substitution for a SU(N) Lie group.