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 thenth comb tooth

图 2相干合成偏振调制光源原理图^[19]

Figure 2.Schematic diagram of polarized modulation light source based on coherent synthesis^[19]

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 inFigure 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 inFig.6(b), obtaining the horizontal and vertical linear polarization states respectively^[19]

图 7(a)q-plate(q=1)对圆偏振光的作用图示^[27]; (b)光频梳与涡旋光结合形成“涡旋光频梳”

Figure 7.(a) Diagram of the effect of aq-plate (q=1) on circularly polarized light^[27]; (b) the “optical vortex comb” by combining optical frequency combs with optical vortices

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 aq-plate into a dual-vortex comb with an adjustable $\Delta {f}_{{\rm{ceo}}}$ and different topological charges

图 9（a）拓扑荷数等量异号的涡旋光束的干涉图样；（b）当 $ \Delta l=4 $ 时，环形晶格周期性旋转的图样

Figure 9.(a) Interference patterns of vortex light with opposite topological charges; (b) images of the optical ring lattice rotates periodically when $\Delta l=4 $

图 10相干合成的轨道角动量调制光源光路图

Figure 10.Schematic diagram of coherently synthesized orbital angular momentum modulated light source

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]