Localization of normalized solutions for saturable nonlinear Schrodinger equations

被引：0

作者：

Wang, Xiaoming ^{[1
]}

Wang, Zhi-Qiang ^{[2
,3
]}

Zhang, Xu ^{[4
]}

机构：

[1] Shangrao Normal Univ, Sch Math & Comp Sci, Shangrao 334001, Peoples R China

[2] Fujian Normal Univ, Coll Math & Stat, Fuzhou 350117, Peoples R China

[3] Utah State Univ, Dept Math & Stat, Logan, UT 84322 USA

[4] Cent South Univ, Sch Math & Stat, Changsha 410083, Peoples R China

来源：

SCIENCE CHINA-MATHEMATICS | 2023年 / 66卷 / 11期

基金：

中国国家自然科学基金;

关键词：

saturable nonlinear Schrodinger equation; normalized solutions; semiclassical states; local maximum potential; CONCENTRATION-COMPACTNESS PRINCIPLE; POSITIVE BOUND-STATES; STANDING WAVES; SEMICLASSICAL STATES; ORBITAL STABILITY; ELLIPTIC PROBLEMS; NODAL SOLUTIONS; GROUND-STATES; EXISTENCE; CALCULUS;

D O I：

10.1007/s11425-022-2052-1

中图分类号：

O29 [应用数学];

学科分类号：

070104 ;

摘要：

In this paper, we study the existence and concentration behavior of the semiclassical states with L-2-constraints for the following saturable nonlinear Schrodinger equation: -epsilon(2)Delta v + Gamma I(x) + v(2)/1 + I(x) + v(2) v = lambda v for x is an element of R-2. For a negatively large coupling constant Gamma, we show that there exists a family of normalized positive solutions (i.e., with the L-2-constraint) when epsilon is small, which concentrate around local maxima of the intensity function I(x) as epsilon -> 0. We also consider the case where I(x) may tend to -1 at infinity and the existence of multiple solutions. The proof of our results is variational and the novelty of the work lies in the development of a new truncation-type method for the construction of the desired solutions.

引用

页码：2495 / 2522

页数：28

共 36 条

[1]

Ambrosetti A, 2007, CAM ST AD M, V104, P1, DOI 10.1017/CBO9780511618260

[2]

Ambrosetti A, 2005, J EUR MATH SOC, V7, P117

[3]

BERESTYCKI H, 1983, ARCH RATION MECH AN, V82, P313

[4] Standing waves with a critical frequency for nonlinear Schrodinger equations [J].

Byeon, J ;

Wang, ZQ .

ARCHIVE FOR RATIONAL MECHANICS AND ANALYSIS, 2002, 165 (04) :295-316

[5] Standing waves for nonlinear Schrodinger equations with singular potentials [J].

Byeon, Jaeyoung ;

Wang, Zhi-Qiang .

ANNALES DE L INSTITUT HENRI POINCARE-ANALYSE NON LINEAIRE, 2009, 26 (03) :943-958

[6] ORBITAL STABILITY OF STANDING WAVES FOR SOME NON-LINEAR SCHRODING EQUATIONS [J].

CAZENAVE, T ;

LIONS, PL .

COMMUNICATIONS IN MATHEMATICAL PHYSICS, 1982, 85 (04) :549-561

[7] Infinitely many bound states for some nonlinear scalar field equations [J].

Cerami, G ;

Devillanova, G ;

Solimini, S .

CALCULUS OF VARIATIONS AND PARTIAL DIFFERENTIAL EQUATIONS, 2005, 23 (02) :139-168

[8] Localized nodal solutions of higher topological type for semiclassical nonlinear Schrodinger equations [J].

Chen, Shaowei ;

Wang, Zhi-Qiang .

CALCULUS OF VARIATIONS AND PARTIAL DIFFERENTIAL EQUATIONS, 2017, 56 (01)

[9] Orbital stability of standing waves for the nonlinear Schrodinger equation with potential [J].

Cid, C ;

Felmer, P .

REVIEWS IN MATHEMATICAL PHYSICS, 2001, 13 (12) :1529-1546

[10]

Dautray R., 1990, Mathematical Analysis and Numerical Methods for Science and Technology, Volume 1: Physical Origins and Classical Method, V1

← 1 2 3 4 →