Zakharov system
The Zakharov system
The Zakharov system consists of a complex field u and a real field n which evolve according to the equations
i u_t + D u = un Box n = -(|u|2)xx
thus u evolves according to a coupled Schrodinger equation, while n evolves according to a coupled wave equation. We usually place the initial data u(0) in H^{s0}, the initial position n(0) in H^{s1}, and the initial velocity nt(0) in H^{s1-1} for some real s0, s1.
This system is a model for the propagation of Langmuir turbulence waves in an unmagnetized ionized plasma [Zk1972]. Heuristically, u behaves like a solution cubic NLS, smoothed by 1/2 a derivative. If one sends the speed of light in Box to infinity, one formally recovers the cubic nonlinear Schrodinger equation. Local existence for smooth data – uniformly in the speed of light! - was established in [KnPoVe1995b] by energy and gauge transform methods; this was generalized to non-scalar situations in [Lau-p], [KeWg1998].
An obvious difficulty here is the presence of two derivatives in the non-linearity for n. To recover this large loss of derivatives one needs to use the separation between the paraboloid t = x2 and the light cone |t| = |x|.
There are two conserved quantities: the L2 norm of u
\int |u|2
and the energy
\int |ux|2 + |n|2/2 + |D-1x nt|2/2 + n |u|2.
The non-quadratic term n|u|2 in the energy becomes difficult to control in three and higher dimensions. Ignoring this part, one needs regularity in (1,0) to control the energy.
Zakharov systems do not have a true scale invariance, but the critical regularity is (s0,s1) = ((d-3)/2, (d-2)/2).
Specific dimensions
- Zakharov equation on R
- Zakharov equation on T
- Zakharov equation on R^2
- Zakharov equation on R^3
- In dimensions d>4 LWP is known on R^d within an epsilon of the critical regularity [GiTsVl1997].
