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摘要: 光学频率梳(光频梳)具有脉冲宽度窄、频率精度高、频率梳齿稳定以及相干性好等优良的时频域特性,近年来成为超快 技术及计量科学等领域的研究热点,并发展成为一种重要的科研工具。近期,一类基于光频梳相干合成的新型光源,可实现对光的偏振或轨道角动量进行射频波段的周期性且高速稳定的调制。本文从光频梳的基本概念出发,分别就偏振调制和轨道角动量调制两个方面,详细介绍了基于光频梳相干合成新型光源的基本原理、实验技术以及表征手段等的最新研究进展。最后简要讨论光频梳相干合成技术在固体光谱学、光学操控、光与物质相互作用等领域的应用前景。Abstract: Optical Frequency Comb (OFC) possesses unique time(frequency) domain characteristics such as narrow pulse width, high frequency precision, stable frequency comb teeth and well-defined optical coherence, etc. Therefore, it has become a hot research topic in various fields including ultra-fast laser technology and metrology science in recent years. Meanwhile, OFC has also been developed into an important scientific research instrument. Recently, a novel light source based on the coherent synthesis of OFCs has been developed, which can realize the periodical, high-speed (up to radio frequency) and stable modulation of the polarization or the orbital angular momentum of light. In this review, we try to introduce recent developments on the fundamental principles, experimental techniques and characterization methods of the novel light source based on the coherent synthesis of OFCs, starting from the basic concepts of OFC and mainly covering two aspects: polarization modulation and orbital angular momentum modulation respectively. We also try to provide some perspectives on the applications of OFC based on the coherent synthesis techniques in the fields of solid-state spectroscopy, optical manipulation and the interaction between light and matter, etc.
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图 1 (a)光频梳的时域表示; (b)光频梳的频域表示。
$ T $ 为脉冲周期;${f}_{{\rm{rep}}}$ 为重复频率;${\phi }_{{\rm{CEP}},{\rm{P}}-{\rm{P}}}$ 为相邻两脉冲间的载波包络相位差;${f}_{{\rm{ceo}}}$ 为载波包络偏移频率;$ {f}_{n} $ 为第n个梳齿的频率Figure 1. (a)The time domain representation and (b) the frequency domain representation of an OFC; T: the pulse repetition period;
${f}_{{\rm{rep}}}$ : the repetition rate;${\phi }_{{\rm{CEP}},{\rm{P}}-{\rm{P}}}$ : the pulse-to-pulse variation of the carrier-envelope phase;${f}_{{\rm{ceo}}}$ : the carrier-envelope offset frequency;$ {f}_{n} $ : the frequency of the nth comb tooth图 3 (a)产生偏振调制光源的第一种方式[19]; (b)产生偏振调制光源的第二种方式[20]。EDFA:掺铒光纤放大器; AOM: 声光调制器; Q: 1/4波片; H(HWP): 半波片; VND: 可变中性密度衰减片; SMF: 单模光纤; PBS: 偏振分束器; BS: 分束器; P: 偏振片
Figure 3. (a) Schematic diagram of the first optical setup to obtain polarization modulated light source[19]; (b) schematic diagram of the second optical setup to obtain polarization modulated light source[20]. EDFA: Er-doped fiber amplifier; AOM: acousto-optical modulator; Q: quarter waveplate; H(HWP): half waveplate; VND: variable neutral density filter; SMF: single-mode fiber; PBS: polarization beam splitter; BS: beam splitter; P: polarizer
图 4 偏振调制光源输出脉冲的偏振态及
$\Delta {\phi }_{{\rm{CEP}}}$ 周期变化图。两光频梳从$ t=0 $ 同时开始传播 (a)当${{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/2$ ,初始${\Delta }{\phi }_{{\rm{CEP}}}=0$ 时; (b)当${{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/2$ ,初始${\Delta }{\phi }_{{\rm{CEP}}}={\text{π}} /2$ 时; (c)当${{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/4$ ,初始${\Delta }{\phi }_{{\rm{CEP}}}=0$ 时; (d)当${{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/4$ ,初始${\Delta }{\phi }_{{\rm{CEP}}}={\text{π}} /4$ 时。注:图中竖线高低代表用于相干合成的两光频梳脉冲对间的$\Delta {\phi }_{{\rm{CEP}}}$ (对($2{\text{π}} )$ 取模之后),同时为了清楚,对$ t=0 $ 时刻的竖线进行了微小偏移Figure 4. Diagram of polarization states of the output pulses of the polarization modulated light source and periodic evolution of
${\Delta }{\phi }_{{\rm{CEP}}}$ . The two optical frequency combs propagate simultaneously starting from$ t=0 $ , (a) when$ {{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/2 $ and initial$ {\Delta }{\phi }_{{\rm{CEP}}}=0 $ ; (b) when$ {{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/2 $ and initial$ \Delta {\phi }_{{\rm{CEP}}}={\text{π}} /2 $ ; (c) when$ {{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/4 $ and initial$ {\Delta }{\phi }_{{\rm{CEP}}}=0 $ ; (d) when$ {{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/4 $ and initial$ \Delta {\phi }_{{\rm{CEP}}}={\text{π}} /4 $ . Note: The height of the vertical lines represents$ {\Delta }{\phi }_{{\rm{CEP}}} $ (after$\mathrm{m}\mathrm{o}\mathrm{d}\left(2{\text{π}}\right)$ ) between pulse pairs from two optical frequency combs which are used for coherent synthesis. The vertical lines at$ t=0 $ have been slightly offset for clarity图 5 用于稳定偏振调制光源输出脉冲的偏振态的电反馈回路结构示意图。注:图中相干合成光路的细节如图3(b)所示,两个功率放大器输出信号分别作用于两个声光调制器上
Figure 5. Schematic diagram of the electrical feedback loop which is used to stabilize the polarization states of the output pulses for the polarization-modulated light source. Note: The details of the optical path for coherent synthesis are shown in Figure 3(b). The two power amplifiers are used to drive the two acousto-optic modulators, respectively
图 6 (a)利用传统的双光梳光谱技术表征偏振调制光源的输出脉冲的偏振态; (b)当
${{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/2$ ,初始${\Delta }{\phi }_{{\rm{CEP}}}=0$ 时,光电探测器探测得到的IGMs; (c)、(d)分别提取图(b)中所有红色和蓝色数据点连接而成的IGM,分别得到水平和垂直线偏振态[19]Figure 6. (a) The polarization states of the output pulses for the polarized modulated light source were characterized by the traditional dual-comb spectroscopy; (b) when
${{\Delta }f}_{{\rm{ceo}}}={f}_{{\rm{rep}}}/2$ , initial${\Delta }{\phi }_{{\rm{CEP}}}=0$ , IGMs were obtained by a fast photodetector. (c)、(d) the IGM formed by extracting all the red and blue points in Fig.6(b), obtaining the horizontal and vertical linear polarization states respectively[19]图 8 (a)相干合成生成环形晶格的实验装置; (b)利用AOM产生具有
$\Delta {f}_{{\rm{ceo}}}$ 可调的双光频梳; (c)利用q-plate将具有$\Delta {f}_{{\rm{ceo}}}$ 可调的双光频梳转换为$\Delta {f}_{{\rm{ceo}}}$ 可调且拓扑荷为等量异号的双涡旋光频梳Figure 8. (a) Experimental setup for coherently synthesized optical ring lattice; (b) generation of a dual-comb with an adjustable
$\Delta {f}_{{\rm{ceo}}}$ using AOM; (c) the dual-comb with an adjustable$\Delta {f}_{{\rm{ceo}}}$ was converted by a q-plate into a dual-vortex comb with an adjustable$\Delta {f}_{{\rm{ceo}}}$ and different topological charges图 11 固定拓扑荷数涡旋光频梳轨道角动量的表征。(a)基于空间部分采样对涡旋光频梳轨道角动量表征的原理; (b)表征轨道角动量的空间部分采样方法[30]; (c)表征轨道角动量的单像素成像方法[31]
Figure 11. Characterization of orbital angular momentum of optical vortex comb with fixed topological charges. (a) Principle of spatial partial sampling to characterize orbital angular momentum of optical vortex comb; (b) spatial partial sampling method for the characterization of orbital angular momentum[30]; (c) single-pixel imaging method for the characterization of orbital angular momentum[31]
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