[1] Liu X F, Peng L P, Zhao Y A et al. Research progress on near-infrared high-power laser damage of liquid crystal optical devices[J]. Chinese Journal of Lasers, 47, 0100002(2020).

[2] Duan Y F, Li F, Yang Z et al. Femtosecond chirped pulse amplification system with liquid crystal spatial light modulator for spectral modulation[J]. Chinese Journal of Lasers, 48, 1101001(2021).

[3] Liu Y J, Cai W F, Li Y et al. Liquid crystal random laser: principles and research progresses[J]. Chinese Journal of Lasers, 48, 1201006(2021).

[4] Wang G, Hou J F, Lin J B et al. Accurate and fast calibration of liquid crystal variable retarder phase delay-voltage curve[J]. Optics and Precision Engineering, 28, 827-833(2020).

[5] Liu T C, Hu J P, Zhu L L et al. Experimental study on birefringence dispersion for liquid crystal mixture by Sellmeier model[J]. Chinese Journal of Lasers, 47, 0804002(2020).

[6] Cao Z L, Peng Z H, Xuan L et al. Design and fabrication of 2 kHz nematic liquid crystal variable retarder with reflection mode[J]. Liquid Crystals, 47, 870-881(2020).

[7] Gupta A K, Fatima A, Nishchal N K et al. Phase imaging based on modified transport of intensity equation using liquid crystal variable retarder with partial coherent illumination[J]. Optical Review, 27, 142-148(2020).

[8] Zhang Y, Xuan J B, Zhao H J et al. Integrated spectral phase delay calibration technique for a liquid crystal variable retarder used in wide-bandwidth working channel[J]. Optics & Laser Technology, 108, 186-192(2018).

[9] Álvarez-Herrero A, Parejo P G, Silva-López M. Fine tuning method for optimization of liquid crystal based polarimeters[J]. Optics Express, 26, 12038-12048(2018).

[10] Yan T Y, Zhang C M, Zhang J R et al. High resolution channeled imaging spectropolarimetry based on liquid crystal variable retarder[J]. Optics Express, 26, 10382-10391(2018).

[11] Soltau D. Instrumental polarization effects of the German vacuum tower telescope (VTT) at Tenerife[J]. Proceedings of SPIE, 2265, 463-467(1994).

[12] Mein P, Rayrole J. Themis solar telescope[J]. Vistas in Astronomy, 28, 567-569(1985).

[13] Medwadowski S J. Structure of the spectroscopic survey telescope (SST)[J]. Proceedings of SPIE, 2199, 366-375(1994).

[14] Volkmer R, von der Luhe O, Soltau D et al. Optical and thermal design of the main optic of the solar telescope GREGOR[J]. Proceedings of SPIE, 5179, 270-281(2003).

[15] Thompson W T, St Cyr O C, Burkepile J T et al. Automatic near-real-time detection of CMEs in Mauna Loa K-Cor coronagraph images[J]. Space Weather, 15, 1288-1299(2017).

[16] Song Z M, Qu Z Q. A novel scanning method applied to new-style solar telescope based on autoguiding system[J]. Advances in Astronomy, 2018, 4575679(2018).

[17] Alvarez-Herrero A, Martínez-Pillet V, del Toro Iniesta J C et al. The IMaX polarimeter for the solar telescope SUNRISE of the NASA long duration balloon program[J]. EPJ Web of Conferences, 5, 05002(2010).

[18] Deng Y Y, Zhang H Y, Yang J F et al. Design of the Full-disk Magneto Graph (FMG) onboard the ASO-S[J]. Research in Astronomy and Astrophysics, 19, 157(2019).

[19] Hou J F, Wang D G, Deng Y Y et al. Interference effect on the liquid-crystal-based Stokes polarimeter[J]. Chinese Physics B, 29, 124211(2020).

[20] Jiang J J, Zhang D Y, Li J F. Liquid crystal variable retarder development and electric-control retardation measurement[J]. Laser Technology, 35, 652-655(2011).

[21] Li J[D]. Research and verification on thermo optic and electro optic characteristics of chiral liquid crystal’s rotatory effect, 64-72(2015).

[22] Yang D K, Wu S T[M]. Fundamentals of liquid crystal devices. Guo T L, Zhou X T, Transl, 301-302(2016).

[23] Liu G Y[D]. Study of thermal stability of LED light source used for CCD calibration, 62-63(2011).