Zakharov system: Difference between revisions

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The Zakharov system
The '''Zakharov system''' consists of a complex field u and a real field n which evolve according to the equations


The Zakharov system consists of a complex field u and a real field n which evolve according to the equations
<center><math>i \partial_t^{} u +  \Delta u = un</math> </center>
<center><math>\Box n = -\Delta (|u|^2_{})</math></center>


i u_t + D u = un
thus <math>u</math> evolves according to a coupled Schrodinger equation, while <math>n</math> evolves according to a coupled wave equation. We usually place the initial data <math>u(0) \in H^{s_0}</math>, the initial position <math>n(0) \in H^{s_1}</math>, and the initial velocity <math>\partial_t n(0) \in H^{s_1 -1}</math> for some real <math>s_0, s_1</math>.
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 to [[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]].


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 <math>n</math>To recover this large loss of derivatives one needs to use the separation between the paraboloid <math>t = x2\,</math> and the light cone <math>|t| = |x|\,</math>.  


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 <math>L^2_x</math> norm of <math>u</math>


There are two conserved quantities: the L2 norm of u
<center><math>\int |u|^2 dx </math></center>
 
\int |u|2


and the energy  
and the energy  


\int |ux|2 + |n|2/2 + |D-1x nt|2/2 + n |u|2.
<center><math>\int |\nabla u|^2 + \frac{|n|^2}{2+ \frac{|D^{-1}_x \partial_t n|^2}{2} + n |u|^2 dx.</math></center>


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.  
The non-quadratic term <math>n|u|^2</math> 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).   
Zakharov systems do not have a true scale invariance, but the critical regularity is <math>(s_0,s_1) = ((d-3)/2, (d-2)/2)</math>.   


== Specific dimensions ==
== Specific dimensions ==


* [[Zakharov equation on R]]
* [[Zakharov system on R]]
* [[Zakharov equation on T]]
* [[Zakharov system on T]]
* [[Zakharov equation on R^2]]
* [[Zakharov system on R^2]]
* [[Zakharov equation on R^3]]
* [[Zakharov system on R^3]]
* In dimensions d>4 LWP is known on R^d within an epsilon of the critical regularity [GiTsVl1997].
* In dimensions d>4 LWP is known on R^d within an epsilon of the critical regularity [[GiTsVl1997]].


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

Latest revision as of 23:58, 2 February 2007

The Zakharov system consists of a complex field u and a real field n which evolve according to the equations

thus evolves according to a coupled Schrodinger equation, while evolves according to a coupled wave equation. We usually place the initial data , the initial position , and the initial velocity for some real .

This system is a model for the propagation of Langmuir turbulence waves in an unmagnetized ionized plasma Zk1972. Heuristically, u behaves like a solution to 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 . To recover this large loss of derivatives one needs to use the separation between the paraboloid and the light cone .

There are two conserved quantities: the norm of

and the energy

The non-quadratic term 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 .

Specific dimensions