1560 nm连续光半导体激光器经PPLN倍频及经铷吸收光谱稳频

将激光器锁定到合适的参考频率上,可以有效地改变激光器的频率稳定性。1560 nm的分布反馈式半导体激光器,可以通过倍频锁定于铷原子吸收线上。实验中我们利用PPLN准位相匹配晶体进行倍频,当输入光为1.6 W时可以获得25 mW的倍频光,非线性转换系数为0.96%/W。我们还将激光器的频率锁定于Rb原子的吸收线上,30 s内剩余频率起伏约为±3.5 MHz。     

采用铷原子射频频率调制光谱与调制转移光谱对1560nm激光经波导倍频至780nm进行稳频的比较

采用射频频率调制光谱(RF-FMS)和调制转移光谱(MTS)将1560nm分布反馈激光器经MgO:PPLN波导高效倍频后锁定于87 Rb原子D2线超精细跃迁。比较了两种方法的原理、谱线以及锁频结果。激光器自由运转30min的典型频率起伏为8~10MHz,采用RF-FMS和MTS锁频30min的频率起伏均方根分别为±135kHz和±85kHz,这主要是由于后者的信噪比高,谱线完全无背景。采用MTS方案,搭建了一套结构紧凑、性能稳定的1.5μm光纤通信波段激光稳频系统。     

520nm泵浦780nm+1560nm双共振光学参量振荡器

我们在实验中演示了520nm单频绿光泵浦的基于周期极化磷酸钛氧钾(PPKTP)晶体的780nm+1560nm双共振光参量振荡器,高效制备780nm+1 560nm连续可调谐双色下转换光场。该参量振荡器可输出93.3 mW的1 560nm单频激光和44.6mW的780nm单频激光。通过改变PPKTP晶体的温度所得到的波长粗调范围为:信号光1 529.81nm~1 573.83nm(~44nm),闲置光788.26nm~777.20nm(~11nm);通过连续调谐520nm泵浦激光频率初步得到的闲置光在780.24nm(铷原子D2线)处频率连续调谐范围约1.6GHz。     

利用外腔谐振倍频产生780nm原子吸收线明亮振幅压缩光

采用连续单频1.56μm激光光源作为泵浦光,通过周期极化铌酸锂晶体外腔倍频过程实验制备出位于原子吸收波线的780nm明亮振幅压缩态光场。在利用2个模清洁器过滤基频光的强度噪声、使之在分析频率4MHz处达到散粒噪声的基础上,利用谐振倍频获得输出功率为10mW、转换效率达40%的倍频光,实测的780nm明亮振幅压缩光的压缩度为0.6dB。     

不同波长的激光器通过法布里-珀罗腔相对于铯原子谱线的锁定

采用共焦法布里珀罗腔(CFP)作为桥梁,可以实现不在原子、分子跃迁线附近的单频激光器相对于原子、分子跃迁线的锁定,从而可以有效地抑制激光频率的漂移。在实验中通过射频频率调制光谱技术结合饱和吸收光谱(SAS)将自制852nm光栅外腔反馈半导体激光器锁定到铯6S1/2Fg=4-6P3/2Fe=4、5交叉线上,通过Pound-Drever-Hall(PDH)射频边带技术将作为桥梁的共焦法布里珀罗腔锁定在852nm激光频率上。再通过PDH方法将830nm和908nm两台远离铯原子D2线的外腔半导体激光器同时锁定在作为桥梁的共焦法布里珀罗腔上,实现了830nm和908nm两台激光器相对于铯原子跃迁线的锁定。由锁定后的误差信号估算,20s内852nm激光器相对于铯原子Fg=4-Fe=4、5交叉线的频率起伏小于±540kHz,830nm、908nm激光器相对于共焦法布里珀罗腔的频率起伏分别小于±340kHz和±60kHz,共焦法布里珀罗腔相对于852nm激光的频率起伏小于±550kHz。     

铷原子饱和吸收光谱与偏振光谱对780nm半导体激光器稳频的比较

将激光频率锁定于合适的参考频率,可以有效地抑制激光器的频率起伏。本文采用铷原子D2线超精细跃迁线的饱和吸收光谱和偏振光谱分别获得鉴频曲线,通过电子伺服系统将频率校正信号负反馈到780 nm光栅外腔反馈半导体激光器外腔的压电陶瓷上的方法对激光器进行稳频。介绍了两种方法的基本原理和实验方案。与激光器自由运转300s时激光器典型的频率起伏约6.6 MHz相比,采用饱和吸收光谱和偏振光谱进行稳频,运转300 s时激光器典型的残余频率起伏分别约为1.5 MHz和0.6 MHz。分析表明,饱和吸收光谱稳频采用了相敏检波技术,需要对激光器进行频率调制,带来了额外的频率噪声,而偏振光谱稳频则是一种完全无频率调制的稳频方案。     

铷原子饱和吸收光谱与偏振光谱对780nm半导体激光器稳频的比较

将激光频率锁定于合适的参考频率,可以有效地抑制激光器的频率起伏。本文采用铷原子D2线超精细跃迁线的饱和吸收光谱和偏振光谱分别获得鉴频曲线,通过电子伺服系统将频率校正信号负反馈到780 nm光栅外腔反馈半导体激光器外腔的压电陶瓷上的方法对激光器进行稳频。介绍了两种方法的基本原理和实验方案。与激光器自由运转300s时激光器典型的频率起伏约6.6 MHz相比,采用饱和吸收光谱和偏振光谱进行稳频,运转300 s时激光器典型的残余频率起伏分别约为1.5 MHz和0.6 MHz。分析表明,饱和吸收光谱稳频采用了相敏检波技术,需要对激光器进行频率调制,带来了额外的频率噪声,而偏振光谱稳频则是一种完全无频率调制的稳频方案。     

准相位匹配周期极化掺镁铌酸锂490 nm倍频连续输出

在室温下通过外加电场极化法,首次用较低的极化开关电场～5.5 kV/mm,在厚为1 mm、长为20 mm、宽为18 mm的掺镁铌酸锂基片上成功的制备了周期为4.8～5.2 μm的一阶准相位匹配倍频光学微结构;并在室温下,以波长为980 nm的半导体激光器为基频光源,对所研制的微结构样品进行倍频通光实验,在入射基频光为800 mW时,产生约40 mW的490 nm的倍频光,其对应转换效率为5%,实验过程中未见绿致吸收光折变现象.     

基于电磁诱导透明效应的无调制里德堡跃迁激光锁频

我们实验上展示了利用室温Rb原子蒸汽池中的电磁诱导透明光谱实现里德堡跃迁激光无调制频率锁定方法。在Rb原子5S_(1/2),5P_(3/2),10D_(3/2)组成的级联三能级系统中,耦合激光工作于原子从中间态5P_(3/2)和里德堡态10D_(3/2)跃迁,探测激光工作于耦合基态5S_(1/2)到中间态5P_(3/2)的跃迁。通过扫描耦合光的频率并测量探测光的光强变化实现EIT信号的监测。我们对探测光进行频率调制,通过解调EIT光谱获得误差信号,并将误差信号经由PID控制电路反馈至激光器进而实现耦合激光频率的锁定。利用这种方法实现了耦合激光的无调制锁频,激光锁定后的残余频率起伏约为1 MHz。这种锁定方法对实现里德堡态原子的高效制备具有重要意义。     

铷原子双共振激发态光抽运光谱及其在1.5μm半导体激光器稳频中的应用

本文介绍分别采用双共振光抽运(DROP)和光学双共振(OODR)光谱技术获得铷原子激发态5P_3/2-4D_3/2 (4D_5/2)之间的超精细跃迁光谱.与传统的OODR光谱相比,DROP光谱在信噪比、线宽等方面具有明显的优势.当1 529 nm光栅外腔半导体激光器的频率采用DROP光谱锁定于～87Rb原子的5P_3/2(F'=3) -4D_3/2(F"=3)超精细跃迁线时,300 s内典型的残余频率起伏为～0.65 MHz;明显优于采用OODR光谱锁频的结果(300 s内典型的残余频率起伏为～1.8 MHz).     

Efficient cw violet-light generation in a ring cavity with a periodically poled KTP

In this work, we experimentally demonstrate an efficient cw second harmonic generation (SHG) at 780 nm wavelength with a first-order type-I phase matching periodically poled KTP (PPKTP) crystal in a ring cavity, the wavelength corresponds to the D₂ line of Rb atom transition. The fundamental laser used is a grating-stabilized external cavity diode laser and its frequency is precisely locked to Rb atom transition frequency using the saturated absorption technique. About maximal 6.9 mW UV radiation of 390 nm with a net conversion of 9.5% at an input mode-matched power of 73 mW is generated with one crystal, and about maximal 8.8 mW with the net conversion of 12% is obtained with another crystal; the powers in stable operation are about 1.7 mW and 3.4 mW, respectively. This is, to our best knowledge, the first SHG experiment at 780 nm wavelength with the PPKTP in a ring cavity.     

半导体激光直接倍频的488nm蓝光激光器

利用波导型准相位匹配周期极化反转铌酸锂(PPLN)晶体直接倍频波长为976 nm的连续半导体激光二极管,在最佳晶体工作温度(28℃)下,获得了波长为488 nm的连续蓝光输出,最大输出功率大于20 mW。所用的晶体尺寸为8 mm×1.4 mm×1 mm,波导截面为4.5μm×3.5μm,极化周期为5.2μm。研究了波导型周期极化反转铌酸锂晶体的倍频效率与温度的关系,与普通的周期极化反转铌酸锂相比,倍频效率与温度关系的敏感度较低。同时,由于晶体可以在室温下工作,简化了加温与温控部件,提高了整机的工作效率。在此实验的基础上,制成了一台小型的全固态488 nm连续蓝光激光器。     

准相位匹配周期极化高掺镁铌酸锂532 nm倍频准连续输出研究

对周期性极化高掺镁铌酸锂倍频过程进行了准相位匹配倍频理论研究。在室温下通过外加电场极化法,用较低的极化开关电场～5．5kV／mm,在厚为1mm、长为10mm、宽为10mm的掺镁铌酸锂基片上成功地制备了周期为5．8～7．3pm(间隔0．3pm)的一阶准相位匹配倍频周期性极化光学微结构。将温度控制在70℃左右,以波长为1．060μm的Nd：YAG激光为基频光源,对所研制的光学微结构样品进行倍频通光实验验证。当入射基频光为920mW时,可以获得约15mW的532nm准连续倍频蓝光输出．其归一化转换效率高达1．77％／W。     

Low-threshold, high-efficiency, high-repetition-rate optical parametric generator based on periodically poled LiNbO3

We report a high-repetition-rate optical parametric generator (OPG) with a periodically poled lithium niobate (PPLN) crystal pumped by an acousto-optically Q-switched CW-diode-end-pumped Nd:YVO_4 laser. For the maximum 1064nm pump power of 970mW, the maximum conversion efficiency is 32.9% under the conditions of 250℃, 1064nm pulse repetition rate of 22.6kHz and pulse width of 12ns, and the PPLN OPG threshold in the collinear case is less than 23.7μJ. The output power increases with the increase of the crystal temperature. The 1485－1553nm signal wave and 3383－3754nm idler wave are obtained by changing the temperature and the angle of the PPLN crystal.     

A frequency-doubled laser system producing ns pulses for rubidium manipulation

We have constructed a pulsed laser system for the manipulation of cold ⁸⁷Rb atoms. The system combines optical telecommunications components and frequency doubling to generate light at 780 nm. Using a fast, fibre-coupled intensity modulator, we sliced output from a continuous laser diode into pulses with a length between 1.3 and 6.1 ns and a repetition frequency of 5 MHz. These pulses are amplified using an erbium-doped fibre amplifier, and frequency-doubled in a periodically poled lithium niobate crystal, yielding a peak power up to 12 W. Using the resulting light at 780 nm, we demonstrate Rabi oscillations on the F=2,m_F=+2↔F^′=3, m^′ _F=+3-transition of a single ⁸⁷Rb atom. PACS 32.80.Qk; 39.25.+k; 42.55.-f     

Light Wave Interactions in Active Nonlinear Crystals with Quadratic Nonlinearity

Recent results in the field of three-frequency wave interaction in homogeneous and inhomogeneous (periodically poled) active nonlinear crystals with quadratic nonlinearity are reviewed. The quasi-phase-matched processes of self-frequency doubling, self-frequency halving, and frequency mixing of the pump and laser radiations are studied. The consecutive quasi-phase-matched processes of the third-harmonic generation and parametric amplification with low-frequency pumping in periodically poled active nonlinear crystals are also investigated. The analysis is carried out for the case of a periodically poled Nd:Mg:LiNbO₃ crystal. Perspectives of using periodically poled active nonlinear crystals in laser devices with self-frequency conversion are discussed.     

低阈值温度调谐PPMgLN红外光参量振荡

研究了温度调谐下周期极化镁掺杂铌酸锂晶体的红外光参量振荡特性。采用外电场短脉冲极化技术,在大小为7.0mm×50.0mm×1.0mm的Z切高镁掺杂(摩尔分数0.05)铌酸锂上制备出了准相位匹配光学微结构器件,极化周期为30.0μm。以输出波长为1064nm的声光调QNd:YAG固体激光器作为基频泵浦光开展了光参量振荡研究。实验表明:泵浦该PPMgLN晶体,实现了室温下低阈值红外光参量振荡产生,阈值功率仅为45mW(重复频率1kHz)。在泵浦输入功率为225mW时,有36mW信号光输出,转换效率达到16.0%,通过调谐晶体温度(20~180℃),获得了调谐范围为1503~1550nm波段的OPO信号光,实现了低阈值可调谐红外光的稳定输出。     

电光晶体调谐的外腔反馈半导体激光器

报道一种用电光晶体实现快速调谐和凋制激光频率的方法.在Littrow型外腔反馈半导体激光中插入LiNbO3晶体,利用LiNbO3晶体的电光效应,通过改变晶体电压来调节激光器的有效腔长,可以对激光频率进行快速的调谐和调制.采用该方法,自制外腔反馈半导体激光器的调谐频率可达到2 kHz,它的调谐范围为350 MHz,激光频率调谐系数约为1.06 MHz/V,用饱和吸收光谱观测频率调谐的效果.快速激光频率调制可以应用在稳频技术上,将外腔反馈半导体激光器调制在5～100 kHz频率下,均获得了87Rb原子D2线的饱和吸收光谱的色散信号,并实现了激光频率在饱和吸收峰上的长期稳定.     

Continuous-wave mid-infrared intracavity singly resonant optical parametric oscillator based on periodically poled lithium niobate

This paper reports a continuous-wave (CW) mid-infrared intracavity singly resonant optical parametric oscillator based on periodically poled lithium niobate (PPLN) pumped by a diode-end-pumped CW Nd:YVO$_{4}$ laser. Considering the thermal lens effects, it adopted an optical ballast lens and the near-concentric cavity for better operation. At the PPLN's grating period of 28.5\,$\mu$m and the temperature of 140\du, the maximum idler output power of 155\,mW at 3.86\,$\mu$m has been achieved when the 808\,nm pump power is 8.5\,W, leading to an optical-to-optical conversion efficiency of 1.82{\%}.