Cubic NLW/NLKG: Difference between revisions

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

Exact solutions

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

${\displaystyle -\Box \phi +\lambda \phi ^{3}=0}$

being ${\displaystyle \,\lambda >0\!}$. An exact solution of this equation is given by

${\displaystyle \phi (x)=\pm \mu \left({\frac {2}{\lambda }}\right)^{1 \over 4}{\rm {sn}}(p\cdot x+\theta ,i),}$

being ${\displaystyle \,{\rm {sn\!}}}$ a Jacobi elliptic function and ${\displaystyle \,\mu ,\theta \!}$ two integration constants, and the following dispersion relation holds

${\displaystyle p^{2}=\mu ^{2}\left({\frac {\lambda }{2}}\right)^{1 \over 2}.}$

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

${\displaystyle \phi (t,0)=\pm \mu \left({\frac {2}{\lambda }}\right)^{1 \over 4}\sum _{n=0}^{\infty }(-1)^{n}{\frac {2\pi }{K(i)}}{\frac {e^{\left(n+{1 \over 2}\right)\pi }}{1+e^{-(2n+1)\pi }}}\sin \left((2n+1){\frac {\pi }{2K(i)}}\left({\frac {\lambda }{2}}\right)^{1 \over 4}\mu t\right)}$

being ${\displaystyle K(i)}$ an elliptic integral. We recognize the "spectrum"

${\displaystyle m_{n}=(2n+1){\frac {\pi }{2K(i)}}\left({\frac {\lambda }{2}}\right)^{1 \over 4}\mu .}$

But a meaning as a mass spectrum can only be given within a quantum field theory FraB2006.

Similarly, when there is a mass term as in

${\displaystyle -\Box \phi +\mu _{0}^{2}\phi +\lambda \phi ^{3}=0}$

the exact solution is given by

${\displaystyle \phi (x)=\pm {\sqrt {\frac {2\mu ^{4}}{\mu _{0}^{2}+{\sqrt {\mu _{0}^{4}+2\lambda \mu ^{4}}}}}}{\rm {sn}}\left(p\cdot x+\theta ,{\sqrt {\frac {-\mu _{0}^{2}+{\sqrt {\mu _{0}^{4}+2\lambda \mu ^{4}}}}{-\mu _{0}^{2}-{\sqrt {\mu _{0}^{4}+2\lambda \mu ^{4}}}}}}\right)}$

being now the dispersion relation

${\displaystyle p^{2}=\mu _{0}^{2}+{\frac {\lambda \mu ^{4}}{\mu _{0}^{2}+{\sqrt {\mu _{0}^{4}+2\lambda \mu ^{4}}}}}.}$

Finally, we can write down the exact solution for the case

${\displaystyle -\Box \phi -\mu _{0}^{2}\phi +\lambda \phi ^{3}=0}$

that is given by

${\displaystyle \phi (x)=\pm v\cdot {\rm {dn}}(p\cdot x+\theta ,i),}$

being ${\displaystyle v={\sqrt {\frac {2\mu _{0}^{2}}{3\lambda }}}}$ and the following dispersion relation holds

${\displaystyle p^{2}={\frac {\lambda v^{2}}{2}}.}$

These wave solutions are interesting as, notwithstanding we started with an equation with a wrong mass sign, the dispersion relation has the right one. Besides, Jacobi function ${\displaystyle \,{\rm {dn}}\!}$ has no real zeros and so the field is never zero but moves around a given constant value that is initially chosen. This effect is known as spontaneous breaking of symmetry in physics.