Theory of noise in a kilo-Hz cascaded high-energy Yb-doped nanosecond pulsed fiber amplifier

A theoretical analysis of noise in a high-power cascaded fiber amplifier is presented. Unlike the noise theory in low power communication, the noise of a high power system is redefined as the leaked output energy between pulses with coherent beat noise uncounted. This definition is more appropriate for high power usage in which the pulse energy receives more attention than the pulse shape integrity. Then the low power pre-amplifying stages are considered as linear amplification and analyzed by linear theory. In the high-power amplification stages, the inversion is assumed to recover linearly in the time interval between pulses. The time shape of the output pulse is different from that of the input signal because of different gains at the front and back ends of the pulse. Then, a criterion is provided to distinguish the nonlinear and linear amplifications based on the signal-to-noise ratio （SNR） analysis. Then, an experiment that shows that the output SNR actually drops off in nonlinear amplification is performed. The change in the noise factor can be well evaluated by pulse shape distortion.     

Observation of wavelength-switchable solitons in an all-polarization-maintaining erbium-doped fiber cavity based on graphene saturable absorber reflector

We present the generation of wavelength-switchable single-polarization solitons in an all-polarization-maintaining erbium-doped fiber laser mode-locked by a graphene saturable absorber. Ultrashort pulses centered at the wavelength of 1531.6 nm with the duration of 816 fs and centered at the wavelength of 1557.8 nm with the duration of 402 fs are separately obtained from the same fiber laser cavity. The cavity loss adjusted by the gold reflector plays a crucial role in wavelength switching.     

Scaling of Yb-doped photonic crystal fiber to 200 μm core diameter for high beam quality laser output

The rare earth-doped active fibers not only have ten thousands of square-micron core-area but also deliver a laser with near-diffraction-limited beam quality. However, they have been studied little. In this paper, we design a 200-μm-corediameter Yb~(3+)-doped photonic crystal fiber with a large pitch in the air-hole cladding region. Simulations demonstrate that only fundamental mode(FM) with a mode field area(MFA) of ～ 28000 μm~2 can be amplified and propagated at the gain saturation, and the beam quality M~2 is about 1.5. It is predicted that almost 105 m J single-pulse energy is available from such a 1.5-meter-length fiber.     

基于1556 nm光纤激光器频率分裂效应的应力测量

光学元件在红外波段的应力-光学常数是众多光学系统关心的问题之一.本文提出一种基于1556.16 nm掺铒光纤激光频率分裂效应的光学玻璃内应力致双折射测量方法.选择平面介质膜腔镜和光纤光栅(FBG)构成线形半开放式谐振腔,并分析了光纤自身弯曲引入谐振腔内的双折射.将待测光学玻璃附带力传感结构放置在谐振腔内,结合Jones矩阵传递方程得到了外载荷所致双折射与空腔双折射的叠加模型.对光学玻璃的载荷从0逐级递加到20 N,内腔的频率分裂量增加,根据双折射叠加模型和频率分裂原理解出应力与频率分裂量的对应关系,且该结果可溯源到基本物理量—波长.实验结果表明,系统灵敏度为22060 Pa/nm,线性度为99.44%,可广泛应用于红外波段的光学元件双折射精确测量.     

太赫兹波段下金属狭缝的透射增强特性研究

用太赫兹时域光谱技术研究了具有不同宽度的金属狭缝透射光谱特征. 实验结果显示在实验测量有效光谱范围(02 THz—26 THz)内,当狭缝宽度小到一定程度,在频谱中出现了共振增强,具有明显的带通带阻现象,并在理论上分析了这种共振透射现象的原因. 关键词： 表面等离子体 太赫兹脉冲 时域光谱技术 金属狭缝     

小波变换在太赫兹时域光谱分析中的应用

随着超快激光技术的发展及其人们对太赫兹(THz)电磁波波段与脉冲光源认识的进一步深入,太赫兹时域光谱(THz-TDS)技术作为一种新的、快速发展的光谱分析方法在许多领域备受关注。利用太赫兹时域光谱技术在空气环境下测量样品时,样品的太赫兹光谱会因空气中水蒸气的影响而出现振荡现象。文章利用太赫兹时域光谱分析技术分别在氮气和空气环境下测量了七种样品在0.2～1.9太赫兹波段的光谱,并以氮气环境下的太赫兹光谱为参考,利用小波变换对空气环境下测量的数据进行了处理,消除了太赫兹光谱中水蒸气吸收造成的影响,实验结果证明了该方法的可行性,在此基础上,还对其中四种样品做了成像和识别,并得到了较好的结果。