1) self-trapping
自俘获
1.
Influence of noise on self-trapping of Bose-Einstein condensates in double-well trap;
噪声对双势阱玻色-爱因斯坦凝聚体系自俘获现象的影响
2.
Two kinds of self-trapping are discussed through phase space analysis in the mean-field approximation: 1) The number of atoms oscillates near an equilibrium point in the phase space, while relative phase increases monotonously with time (running-phase); 2) Both the number of particles and the relative phase oscillate near an equilibrium point in the phase space.
研究了双势阱玻色-爱因斯坦凝聚体系(BEC)的自俘获现象(self-trapping)。
3.
We investigate the Josephson oscillation and transition to self-trapping for Bose-Eiristein-Condensates(BECs) in a triple-well trap.
我们使用平均场方法研究了三势阱中玻色-爱因斯坦凝聚体(BECs)的约瑟夫森振荡和自俘获。
2) self-trapping effect
自俘获效应
1.
A discussion is given about the self-trapping effect for a single pulse of soliton,which can prevent a soliton pulse with PMD from splitting.
研究了偏振模色散效应对于光孤子传输系统的影响:首先在单个孤子脉冲的情况下,讨论了光孤子的自俘获效应对于偏振模色散的自适应能力,进而考虑更有意义的脉冲序列的情况,即因PMD引起的两个光孤子之间的相互作用以及能量损失而带来的系统损耗的问题。
4) self trapped electron
自俘获电子
5) self trapped exciton
自俘获激子
6) soliton self-trapping
孤子自俘获
1.
2) Soliton self-trapping is realized using the SPM and XPM of PCF, and the influence of PCF characteristic parameters such as group velocity mismatch factor, third-order dispersion, the steep factor and pulse within the raman scattering factor on soliton self-trapping is researched using Matlab based on split-step fourier method in the anomalous dispersion regime of PCF.
2)利用光子晶体光纤的自相位调制和交叉相位调制效应实现孤子自俘获,并基于分步傅里叶方法,利用Matlab仿真分析了在光子晶体光纤的反常色散区,光子晶体光纤的特性参数如群速度失配因子、三阶色散、自陡峭因子和脉冲内拉曼散射因子对孤子自俘获效应的影响。
2.
Based on step-by-step Fourier method,the influences of group velocity mismatch factor δ and high-order dispersion on soliton self-trapping in the photonic crystal fiber is numerically investigated.
基于分步傅里叶方法,仿真研究了光子晶体光纤(PCF)在反常色散区的群速度失配因子δ、高阶色散(主要是三阶色散)对孤子自俘获效应的影响。
补充资料:自调自净自度
【自调自净自度】
(术语)同自调项。
(术语)同自调项。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条