1 河北工业大学 先进激光技术研究中心,天津 300401
2 河北省先进激光技术与装备重点实验室,天津 300401
3 电磁空间安全全国重点实验室,天津 300308
4 哈尔滨工业大学 可调谐激光技术国家重点实验室,黑龙江 哈尔滨 150001
腔长微调节结构在光学谐振器里有重要应用。一种由双楔镜组成的腔长微调节结构被提出,该结构可实现不依赖于腔镜的腔长调节。双楔镜结构由斜面平行对立放置的两个直角楔镜构成,通过在垂直方向上驱动楔镜移动实现双楔镜内部光程改变,进而改变所处谐振腔内光路的光程。双楔镜结构对光程改变量的理论计算公式被建立,根据公式,光程改变量与楔镜楔角大小成正相关关系,与楔镜折射率成正相关关系,与楔镜振幅成线性关系。楔镜的楔角和折射率共同决定双楔镜结构的光程调节效率。经理论设计,楔角29°、折射率1.81的YAG双楔镜结构具有较高的调节效率和较小的光损耗,调节系数为0.53。实验上,以双角锥环形腔为基础,实现了双楔镜结构对腔长的调节,验证确定了双楔镜结构对腔长调节的可行性和有效性。讨论分析了双楔镜结构的变形结构:直角面对立双楔镜结构、基于正楔镜的双楔镜结构、多级双楔镜结构的光程调节性能。对比了双楔镜结构和其变形结构在光程调节效率、光损耗、光路调节难易程度的性能,确定了各种双楔镜结构在实际应用中的优缺点,为双楔镜结构的设计和选择提供了参考依据。
双楔镜 腔长调节 楔角 PZT double optical wedge cavity length adjustment wedge prism PZT 红外与激光工程
2023, 52(8): 20230422
Author Affiliations
Abstract
State Key Laboratory on Integrated Optoelectronics, College of Electronic Science and Engineering, Jilin University, Changchun 130012, China
A photonic approach is proposed to generate microwave arbitrary waveforms based on the stimulated Brillouin scattering (SBS) effect and the Sagnac loop. The Sagnac loop is utilized to generate the optical signals of ±1st-order and ±3rd-order sidebands. Due to the principle of velocity adaptation, even order optical sidebands are suppressed. Thanks to the SBS effect, the microwave signal consisting of odd order harmonics is generated after the photodetector (PD), which can construct the triangular waveform, the square waveform, or the sawtooth waveform by adjusting the weight of the harmonics.
光电子快报(英文版)
2021, 17(6): 379
Author Affiliations
Abstract
National Key Laboratory of Tunable Laser Technology, Harbin Institute of Technology, Harbin 150001, China
We demonstrate a single-longitudinal-mode Ho3+:YVO4 unidirectional ring laser based on the acousto-optic effect, utilizing the features of the acousto-optical Q switch and half-wave plate to achieve unidirectional operation. The maximum power achieved in the single-longitudinal-mode at 2053.9 nm is 941 mW when the absorbed power is set as 4.4 W, yielding a nearly 50% slope efficiency. The M2 factor is 1.1. The results show that such a technique offers a potentially promising new method for achieving a high power and narrow linewidth 2 μm single-longitudinal-mode laser.
140.3560 Lasers, ring 140.3570 Lasers, single-mode 140.3580 Lasers, solid-state Chinese Optics Letters
2017, 15(3): 031402
Author Affiliations
Abstract
National Key Laboratory of Tunable Laser Technology, Harbin Institute of Technology, Harbin 150080, China
We demonstrate a diode-pump Tm3+-doped all-fiber laser operating at 1908 nm based on a master oscillator power amplifier (MOPA) configuration. In our work, 152 W of laser output power is generated by a total incident pump power of 434 W at 790 nm, corresponding to the total optical efficiency of 35%. The laser wavelength is 1908.29 nm. To the best of our knowledge, it is the highest output power reached around 1908 nm with such a narrow linewidth of 0.18 nm based on a MOPA configuration.
140.3510 Lasers, fiber 060.2320 Fiber optics amplifiers and oscillators 060.2390 Fiber optics, infrared Chinese Optics Letters
2016, 14(6): 061403
燕山大学电气工程学院, 河北 秦皇岛 066004
构建了一种金属-绝缘体-金属(MIM)表面等离子体布拉格波导结构,绝缘层为一维布拉格光栅结构。在布拉格光栅结构中引入缺陷,形成布拉格纳米微腔。这种纳米微腔结构可以将光子能量很好地局域在微腔中,且在金属与绝缘层界面上光子能量最强。分析了MIM 波导的色散特性,获得了谐振波长为1550 nm 时微腔的结构参数。同时利用时域有限差分(FDTD)方法讨论了绝缘层布拉格光栅周期数、绝缘层厚度、微腔长度对微腔品质因子Q 和模式体积V 的影响。通过合理的选择这些参数可以提高微腔性能,使其具有极小的模式体积V 和高的Q/V 值,可实现光子局域化。
光学器件 表面等离子体 MIM 波导 布拉格光栅 纳米微腔
燕山大学电气工程学院, 河北 秦皇岛 066004
构建了一种三层混合光子晶体等离子体激元结构,分别为金属银(Ag)层,低折射率二氧化硅(SiO2)层和二维光子晶体层。这种混合光子晶体等离子体激元结构具有明显的横磁模(TM)模式带隙。在二维的光子晶体层的中心引入一个单元胞缺陷,形成缺陷腔结构。这种纳米尺度的光子晶体等离子体微腔的体积远小于传统介质的光学微腔,光子能量可以很好地被局域到低折射率层,实现了深亚波长尺度下的对光的限制。通过改变该混合光子晶体等离子激元结构的参数,利用三维时域有限差分(3D-FDTD)方法,分析了这种混合光子晶体等离子微腔结构的光学特性。分析表明:这种纳米微腔具有极小的模式体积0.0141 (λ/n)3和高的Q/V值。
光学器件 表面等离子体 光子晶体 纳米微腔 模式体积
