Ultra-thin Photonic Crystal Mirror for Vertical-cavity Surface-emitting Lasers

Haijing WANG; Jun WANG; Jiachen LI; Chunyang XIAO; Yanxing JIA; Rui MING; Bojie MA; Zhuoliang LIU; Kai LIU; Yiming BAI; Yongqing HUANG; Xiaomin REN

doi:10.3788/gzxb20225109.0914002

[1] Fengling WANG, Lei CHEN, Qiubo ZHANG et al. Design of high contrast subwavelength gratings with GaAs-based VCSEL materials. Journal of Infrared and Millimeter Waves, 39, 19-24(2020).

[2] M C Y HUANG, Y ZHOU, C J CHANG-HASNAIN et al. A surface-emitting laser incorporating a high-index-contrast subwavelength grating. Nature Photonics, 1, 297-297(2007).

[3] Xiushan LI, Yongqiang NING, Xing ZHANG et al. Influence of grating parameters on reflectivity of Si/SiO2 high contrast gratings. Chinese Journal of Luminescence, 36, 806-810(2015).

[4] Baoqiang WANG, Chen XU, Yingming LIU et al. Study on current spreading of photonic crystal vertical cavity surface emitting lasers. Chinese Journal of Physics, 59, 8542-8547(2010).

[5] Y ITOH, N KONO, N FUJIWARA et al. Continous-wave lasing operation of 1.3-μm wavelength InP-based photonic crystal surface-emitting lasers using MOVPE regrowth. Optics Express, 28, 35483(2020).

[6] M YOSHIDA, M D ZOYSA, K ISHIZAKI et al. Double-lattice photonic-crystal resonators enabling high-brightness semiconductor lasers with symmetric narrow-divergence beams. Nature Materials, 18, 121-128(2019).

[7] M DE ZOYSA, M YOSHIDA, M KAWASAKI et al. Photonic crystal lasers fabricated by MOVPE based on organic arsenic source. IEEE Photonics Technology Letters, 29, 1739-1742(2017).

[8] M YOSHIDA, M KAWASAKI, M DE ZOYSA et al. Fabrication of photonic crystal structures by tertiary-butyl arsine-based metal–organic vapor-phase epitaxy for photonic crystal lasers. Applied Physics Express, 9, 062702(2016).

[9] K J REILLY, A KALAPALA, S YEOM et al. Epitaxial regrowth and hole shape engineering for photonic crystal surface emitting lasers (PCSELs). Journal of Crystal Growth, 535, 125531(2020).

[10] B DEMEULENAERE, P BIENSTMAN, B DHOEDT et al. Detailed study of AlAs-oxidized apertures in VCSEL cavities foroptimized modal performance. IEEE Journal of Quantum Electronics, 35, 358-367(1999).

[11] Xiaoming HAN, Dexing YANG, Jianlin ZHAO et al. Thermal effect in high-power Yb3+-doped photonic crystal fiber lasers. Chinese Journal of Lasers, 36, 2822-2826(2009).

[12] W NAKWASKI. Thermal conductivity of binary, ternary, and quaternary III-V compounds. Journal of Applied Physics, 64, 159-166(1988).

[13] M OSINSKI, W NAKWASKI. Effective thermal conductivity analysis of 1.55 μm InGaAsP/InP vertical-cavity top-surface-emitting microlasers. Electronics Letters, 11, 1015-1016(1993).

[14] H K LEE, Y M SONG, Y T LEE et al. Thermal analysis of asymmetric intracavity-contacted oxide-aperture VCSELs for efficient heat dissipation. Solid-State Electronics, 53, 1086-1091(2009).

[15] Hui LI, Xiaowei JIA, Zekun WEI et al. Thermal analysis and structure optimization of high-speed optical communication-VCSEL. Chinese Journal of Luminescence, 38, 1516-1522(2017).