[1] Wenjun He, Wentao Jia, Qi Wang, et al. Polarization evolution of radial vector field on double retarders. Infrared and Laser Engineering, 48, 0517006(2019).

[2] Sicong Wang, Xiangping Li. Wavefront manipulation of tightly focused cylindrical vector beams and its applications. Chinese Optics, 9, 185-202(2016).

[3] Tongda Wei, Yunhai Zhang, Yuguo Tang. Effect of polarization, phase and amplitude on depletion focus spot in STED. Optics and Precision Engineering, 22, 1157-1164(2014).

[4] Xinchun Tang, Jiancun Gao, Kun Wang, et al. Generation of a radially polarized light and its application. Laser & Optoelectronics Progress, 50, 030001(2013).

[5] Hongpan Peng, Ce Yang, Shang Lu, et al. All- solid-state picosecond radially polarized laser and its processing characteristics. Infrared and Laser Engineering, 48, 0106003(2019).

[6] Jinchao Dang, Chengjin Fan, Haoran Li, et al. Tight focusing of radially polarized power-exponent-phase vortex beam. Journal of Optoelectronics · Laser, 29, 453-458(2018).

[7] C Varin, S Payeur, V Marceau, et al. Direct electron acceleration with radially polarized laser beams. Applied Sciences, 3, 70-93(2013).

[8] Shaohui Li, Xiaomei Chen, Guoqiang Ni. Highly precise ground certification system of satellite laser communication. Optics and Precision Engineering, 25, 1149-1158(2017).

[9] Hongliang Wang, Jingqiu Liang, Zhongzhe Liang, et al. Analysis and design of Fourier transform polarization interference imaging system. Chinese Optics, 12, 638-648(2019).

[10] W Koechner, D K Rice. Effect of birefringence on the performance of linearly polarized YAG:Nd lasers. Journal of Quantum Electronics, QE-6, 557-566(1970).

[11] Yantao Dong, Zhigang Zhao, Chong Liu, et al. Influence of thermal effects on polarizability and output character of TEM₀₀-mode of solid state laser. Chinese Journal of Lasers, 36, 1759-1765(2009).

[12] [12] Timoskenko S, Goodier J N. They of Elasticity[M]. New Yk: McGrawHill, 1951: 150.

[13] Q Lu, U Wittrock, S Dong. Photoelastic effect in Nd:YAG rod and slab lasers. Optics & Laser Technology, 27, 95-101(1995).

[14] Y Lumer, I Moshe, S Jackel, et al. Depolarization induced by pumped edge effects in high average power laser rods. Journal of the Optical Society of America B, 27, 38-44(2010).

[15] A Matijošius, P Stanislovaitis, T Gertus, et al. Formation of optical vortices with topological charge |l|=1 and |l|=1/2 by use of the S-waveplate. Optics Communications, 324, 1-9(2014).

[16] Hongpan Peng, Ce Yang, Shang Lu, et al. Radially polarized beam purity detection and evaluation of polarization distribution characteristics. Infrared and Laser Engineering, 48, 0506007(2019).

[17] Zhengwei Li, Meng Chen, Gang Li. Side-pumped Nd:YAG mode-locked radially polarized laser. Chinese Journal of Lasers, 41, 0102006(2014).

[18] Q Lü, N Kugler, H Weber, et al. A novel approach for compensation of birefringence in cylindrical Nd:YAG rods. Optical and Quantum Electronics, 28, 57-69(1996).

[19] Zhigang Li, Haili Zhao, Peng Liu, et al. Measurement system of crystal specific rotation. Opt-Electronic Engineering, 42, 78-82(2015).

[20] T Graupeter, R Hartmann, C Pflaum. Calculations of eigenpolarization in Nd:YAG laser rods due to thermally induced birefringence. IEEE Journal of Quantum Electronics, 50, 1035-1043(2014).

[21] Chong Liu, Jiangong Ge, Zhen Xiang, et al. Thermal-induced birefringence-compensated laser system with two Nd:YAG rods. Chinese Journal of Lasers, 34, 1483-1487(2007).