niobate crystal meaning in English
铌酸盐晶体
Examples
- Test method for bulk acoustic wave attenuation of piezoelectric lithium niobate crystals
压电铌酸锂单晶体声波衰减测试方法 - We studied the mechanism of the visible light - induced domain switching in the lithium niobate crystals , and considered that the main factor is the movement of light - induced carrier , which modified the local electric field in the crystals and then resulted in the reduction of the domain switching voltage
探寻了可见光诱导铌酸锂晶体畴反转的形成机制,认为光诱导晶体畴反转的主要原因是光激载流子迁移改变了晶体内部的局域电场,造成了晶体极化反转电压的降低。 - After analyzing the characteristics of the lithium niobate crystal and the principle of electro - optic phase modulation & the coupling of single - mode fiber with optical waveguide , the fabrication of the single - mode lithium niobate bar waveguide and v - groove has been studied , the new project in which the lithium niobate v - groove is used for the coupling of the single - mode fiber with optical waveguide is put forward
在分析了铌酸锂晶体的相关特性、电光相位调制的基本原理以及单模光纤和光波导的对接耦合以后,研究了单模铌酸锂条形波导和铌酸锂v型槽的制作工艺,提出了使用铌酸锂v型槽实现单模光纤与波导耦合的方案。 - With the existing condition , the bar waveguide on the lithium niobate wafer with liquid phase proton - exchanged method has been fabricated and the benzoic acid is used as the proton source . a series of research on the domain inversion in lithium niobate crystal with proton - exchanged method have been done . and then the operation and the process of domain inversion in lithium niobate crystal with proton - exchanged method has been used
实验方面,利用实验室现有条件,在铌酸锂晶片上以苯甲酸为质子源,用液相质子交换法制作了条形波导;对用质子交换法实现铌酸锂晶体畴反转进行了一系列实验研究,在此基础上提出了质子交换法实现铌酸锂晶体畴反转的工艺过程,实现了畴反转并腐蚀得到了v型槽;设计制作了带尾纤的电光相位调制器,最后进行封装。 - Iron - doped photorefractive lithium - niobate crystals ( linbo3 : fe ) have good electro - optic , acoustic - optic , nonlinear characterizations , and hardly light absorption and photorefractive sensitivity in the wavelength around 1550nm , which makes them attractive for using as passive optical components in telecommunication networks
而光折变linbo _ 3 : fe晶体具有良好的电光、声光以及非线性特性,且在现有的通信窗口1550nm波长处几乎没有光吸收,对光的敏感性很小,是光折变光栅应用于光通信系统的首选材料。