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This study investigates how linear coupling affects spatial localization in waveguides with asymmetric defocusing nonlinearity.

June 3, 2026Open Access

Coupling-induced localization in linearly coupled waveguides with spatially modulated nonlinearity

Key Points

This study investigates how linear coupling affects spatial localization in waveguides with asymmetric defocusing nonlinearity.
Analyzed stationary modes in coupled nonlinear Schrödinger equations.
Computed fundamental and excited stationary modes, examining their existence and stability.
Conducted dynamical simulations to assess stability across various coupling strengths.
Dynamical simulations revealed stable ground and first excited states, while higher-order modes were unstable.
Stable modes depended on coupling strength and nonlinearity.
The study demonstrated that linear coupling can induce localization in nonlocalizing waveguides.

Abstract

Abstract We study stationary, spatially localized modes in linearly coupled optical waveguides governed by coupled nonlinear Schrödinger equations with asymmetric defocusing Kerr nonlinearities. A waveguide with spatially inhomogeneous nonlinearity supports self-trapped states, whereas a homogeneous defocusing waveguide cannot localize on its own. We show that linear coupling induces localization in the nonlocalizing guide. Fundamental and excited stationary modes are computed, and their existence, power asymmetry, and stability are analyzed as functions of the coupling strength and nonlinearity. Dynamical simulations reveal stable ground and first excited states, whereas higher-order modes are unstable. These results demonstrate coupling-induced spatial localization in defocusing nonlinear waveguide systems.

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Coupling-induced localization in linearly coupled waveguides with spatially modulated nonlinearity

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Abstract

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