Zakharov system: Difference between revisions

Revision as of 03:45, 28 July 2006

The Zakharov system

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

$i\partial _{t}^{}u+\Delta u=un$

$\Box n=-\Delta (|u|_{}^{2})$

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 $H^{s_{0}}$ , the initial position $n(0)$ in $H^{s_{1}}$ , and the initial velocity $/partial_{t}n(0)$ in $H^{s_{1}-1}$ for some real $s_{0},s_{1}$ .

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 $L_{x}^{2}$ norm of $u$

$\int |u|2dx$

and the energy

$\int |ux|2+|n|2/2+|D-1xnt|2/2+n|u|2dx.$

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

@@ Line 3: / Line 3: @@
 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
+<math>i \partial_t^{} u +  \Delta u = un</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.
+<math>\Box n = -\Delta (|u|^2_{})</math>
+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)</math> in <math>H^{s_0}</math>, the initial position <math>n(0)</math> in <math>H^{s_1}</math>, and the initial velocity <math>/partial_t n(0)</math> in <math>H^{s_1 -1}</math> for some real <math>s_0, s_1</math>.
 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|.
+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 t = x2 and the light cone <math>|t| = |x|</math>.
-There are two conserved quantities: the L2 norm of u
+There are two conserved quantities: the <math>L^2_x</math> norm of <math>u</math>
-\int |u|2
+<math>\int |u|2 dx </math>
 and the energy
-\int |ux|2 + |n|2/2 + |D-1x nt|2/2 + n |u|2.
+<math>\int |ux|2 + |n|2/2 + |D-1x nt|2/2 + n |u|2 dx.</math>
 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 system: Difference between revisions

Revision as of 03:45, 28 July 2006

Specific dimensions

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