关于腔隙孤子的时空镊合

IF 1.4 4区 物理与天体物理 Q2 MATHEMATICS, APPLIED
Julia Rossi, Sathyanarayanan Chandramouli, Ricardo Carretero-González, Panayotis G. Kevrekidis
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引用次数: 0

摘要

在 Jang 等人的研究成果(Nat Commun 6:7370 (2015))的激励下,我们研究了当局部镊子的特性发生变化时,空穴孤子是否可以被镊子镊断。该系统由 Lugiato-Lefever 方程建模,它是复杂金兹堡-兰道方程的一个变体。我们通过假设保持光束的高斯相位调制,产生了一个有效的局部诱捕镊子电势。然后,随着镊子总(时间)位移和速度的变化,对镊子的电位进行评估,并给出相应的相图。随着镊子相对速度的增加,我们发现了两种可能的动态情况:成功镊取和释放空穴孤子。我们还采用了基于拉格朗日描述的非保守变分近似(NCVA)方法,将原来的耗散偏微分方程简化为空穴孤子参数的一组耦合常微分方程。我们展示了 NCVA 准确预测成功和失败镊合之间分离矩阵的能力。这展示了 NCVA 的多功能性,它提供了时空镊合实验实现的低维描述。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

On the Temporal Tweezing of Cavity Solitons

On the Temporal Tweezing of Cavity Solitons

Motivated by the work of Jang et al., Nat Commun 6:7370 (2015), where the authors experimentally tweeze cavity solitons in a passive loop of optical fiber, we study the amenability to tweezing of cavity solitons as the properties of a localized tweezer are varied. The system is modeled by the Lugiato-Lefever equation, a variant of the complex Ginzburg-Landau equation. We produce an effective, localized, trapping tweezer potential by assuming a Gaussian phase-modulation of the holding beam. The potential for tweezing is then assessed as the total (temporal) displacement and speed of the tweezer are varied, and corresponding phase diagrams are presented. As the relative speed of the tweezer is increased we find two possible dynamical scenarios: successful tweezing and release of the cavity soliton. We also deploy a non-conservative variational approximation (NCVA) based on a Lagrangian description which reduces the original dissipative partial differential equation to a set of coupled ordinary differential equations for the cavity soliton parameters. We illustrate the ability of the NCVA to accurately predict the separatrix between successful and failed tweezing. This showcases the versatility of the NCVA to provide a low-dimensional description of the experimental realization of the temporal tweezing.

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来源期刊
Journal of Nonlinear Mathematical Physics
Journal of Nonlinear Mathematical Physics PHYSICS, MATHEMATICAL-PHYSICS, MATHEMATICAL
CiteScore
1.60
自引率
0.00%
发文量
67
审稿时长
3 months
期刊介绍: Journal of Nonlinear Mathematical Physics (JNMP) publishes research papers on fundamental mathematical and computational methods in mathematical physics in the form of Letters, Articles, and Review Articles. Journal of Nonlinear Mathematical Physics is a mathematical journal devoted to the publication of research papers concerned with the description, solution, and applications of nonlinear problems in physics and mathematics. The main subjects are: -Nonlinear Equations of Mathematical Physics- Quantum Algebras and Integrability- Discrete Integrable Systems and Discrete Geometry- Applications of Lie Group Theory and Lie Algebras- Non-Commutative Geometry- Super Geometry and Super Integrable System- Integrability and Nonintegrability, Painleve Analysis- Inverse Scattering Method- Geometry of Soliton Equations and Applications of Twistor Theory- Classical and Quantum Many Body Problems- Deformation and Geometric Quantization- Instanton, Monopoles and Gauge Theory- Differential Geometry and Mathematical Physics
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