Semilinear Schrodinger equation: Difference between revisions

**NLS**
Description
Equation
Fields
Data class
Basic characteristics
Structure	Hamiltonian
Nonlinearity	semilinear
Linear component	Schrodinger
Critical regularity
Criticality	varies
Covariance	Galilean
Theoretical results
LWP	for (*)
GWP	varies
Related equations
Parent class	Nonlinear Schrodinger equations
Special cases	quadratic, cubic, quartic, quintic,; mass critical NLS
Other related	NLS with potential, on manifolds

Latest revision as of 05:44, 21 July 2007

The semilinear Schrodinger equation (NLS) is displayed on the right-hand box, where the exponent p is fixed and is larger than one. One can also replace the nonlinearity $\pm |u|^{p-1}u$ by a more general nonlinearity $F(u)$ of power type. The $+$ sign choice is the defocusing case; $-$ is focusing. There are also several variants of NLS, such as NLS with potential or NLS on manifolds and obstacles; see the general page on Schrodinger equations for more discussion.

Theory

The NLS has been extensively studied, and there is now a substantial theory on many topics concerning solutions to this equation.

Algebraic structure (Symmetries, conservation laws, transformations, Hamiltonian structure)
Well-posedness (both local and global)
Scattering (as well as asymptotic completeness and existence of wave operators)
Stability of solitons (orbital and asymptotic)
Blowup
Unique continuation

Specific semilinear Schrodinger equations

There are many special cases of NLS which are of interest:

Quadratic NLS
Cubic NLS (on R, on R^2, on R^3, etc.)
Quartic NLS
Quintic NLS (on R, on T, on R^2, and on R^3)
Septic NLS
Mass critical NLS
Energy critical NLS

@@ Line 1: / Line 1: @@
-[Many thanks to Kenji Nakanishi with valuable help with the scattering theory portion of this section. However, we are still missing many references and results, e.g. on NLS blowup. - Ed.]
+{{equation
+ | name = NLS
+ | equation = <math>iu_t + \Delta u = \pm |u|^{p-1} u</math>
+ | fields = <math>u: \R \times \R^d \to \mathbb{C}</math>
+ | data = <math>u(0) \in H^s(\R^d)</math>
+ | hamiltonian = [[Hamiltonian]]
+ | linear = [[free Schrodinger equation|Schrodinger]]
+ | nonlinear = [[semilinear]]
+ | critical = <math>\dot H^{\frac{d}{2} - \frac{2}{p-1}}(\R^d)</math>
+ | criticality = varies
+ | covariance = [[Galilean]]
+ | lwp = <math>H^s(\R)</math> for <math>s \geq \max(s_c, 0)</math> (*)
+ | gwp = varies
+ | parent = [[Schrodinger equations|Nonlinear Schrodinger equations]]
+ | special = [[Quadratic NLS|quadratic]], [[cubic NLS|cubic]], [[quartic NLS|quartic]], [[quintic NLS|quintic]],<br> [[mass critical NLS|mass critical]] NLS
+ | related = NLS [[NLS with potential|with potential]], [[NLS on manifolds and obstacles|on manifolds]]
+}}
-The '''semilinear Schrodinger equation''' (NLS) is
-<center><math>i \partial_t u + \Delta u = \pm |u|^{p-1} u </math></center>
+The '''semilinear Schrodinger equation''' (NLS) is displayed on the right-hand box, where the exponent ''p'' is fixed
+and is larger than one.  One can also replace the nonlinearity <math>\pm |u|^{p-1} u</math> by a more general nonlinearity
+<math>F(u)</math> of [[power type]].  The <math>+</math> sign choice is the [[defocusing]] case; <math>-</math> is [[focusing]]. There are also several variants of NLS, such as [[NLS with potential]] or [[NLS on manifolds and obstacles]]; see the general page on [[Schrodinger equations]] for more discussion.
-for p>1.  There are many [[Schrodinger:specific equations|specific cases]] of this equation which are of interest, but in this page we shall focus on the general theory. The <math>+</math> sign choice is the ''defocusing'' case; <math>-</math> is ''focussing''. There are also several variants of NLS, such as [[NLS with potential]] or [[NLS on manifolds and obstacles]]; see the general page on [[Schrodinger equations]] for more discussion.
+== Theory ==
-== Theory ==
+The NLS has been extensively studied, and there is now a substantial theory on many topics concerning solutions to this equation.
 * [[Algebraic structure of NLS|Algebraic structure]] (Symmetries, conservation laws, transformations, Hamiltonian structure)
-* [[NLS wellposedness|Local and global well-posedness theory]]
+* [[NLS wellposedness|Well-posedness]] (both local and global)
-* [[NLS scattering|Scattering theory]]
+* [[NLS scattering|Scattering]] (as well as asymptotic completeness and existence of wave operators)
+* [[NLS stability|Stability of solitons]] (orbital and asymptotic)
 * [[NLS blowup|Blowup]]
 * [[Unique continuation]]
 == Specific semilinear Schrodinger equations ==
+There are many special cases of NLS which are of interest:
 * [[Quadratic NLS]]
 * [[Cubic NLS]] ([[cubic NLS on R|on R]], [[cubic NLS on R2|on R^2]], [[cubic NLS on R3|on R^3]], etc.)
 * [[Quartic NLS]]
-* [[Quintic NLS]]
+* [[Quintic NLS]] ([[Quintic NLS on R|on R]], [[Quintic NLS on T|on T]], [[Quintic NLS on R2|on R^2]], and [[Quintic NLS on R3|on R^3]])
 * [[Septic NLS]]
 * [[Mass critical NLS]]
+* [[Energy critical NLS]]
 [[Category:Equations]]
 [[Category:Schrodinger]]

Description
Equation	$iu_{t}+\Delta u=\pm \|u\|^{p-1}u$
Fields	$u:\mathbb {R} \times \mathbb {R} ^{d}\to \mathbb {C}$
Data class	$u(0)\in H^{s}(\mathbb {R} ^{d})$
Basic characteristics
Structure	Hamiltonian
Nonlinearity	semilinear
Linear component	Schrodinger
Critical regularity	${\dot {H}}^{{\frac {d}{2}}-{\frac {2}{p-1}}}(\mathbb {R} ^{d})$
Criticality	varies
Covariance	Galilean
Theoretical results
LWP	$H^{s}(\mathbb {R} )$ for $s\geq \max(s_{c},0)$ (*)
GWP	varies
Related equations
Parent class	Nonlinear Schrodinger equations
Special cases	quadratic, cubic, quartic, quintic, mass critical NLS
Other related	NLS with potential, on manifolds

Semilinear Schrodinger equation: Difference between revisions

Latest revision as of 05:44, 21 July 2007

Theory

Specific semilinear Schrodinger equations

Navigation menu

Page actions

Page actions

Personal tools

orientation

Search

Categories

development

Tools