Simulation of structural design with high coupling efficiency in external cavity semiconductor laser

Yangjie Zhang; Wentao Guo; Di Xiong; Xiaofeng Guo; Wenyuan Liao; Haifeng Liu; Weihua Liu; Manqing Tan

doi:10.1088/1674-4926/40/10/102302

[1] B Lu, F Wei, Z Zhang et al. Research on tunable local laser used in ground-to-satellite coherent laser communication. Chin Opt Lett, 13, 091402(2015).

[2] B Mroziewicz. External cavity wavelength tunable semiconductor lasers-a review. Opto-Electron Rev, 16, 347(2008).

[3]

[4] B Liu, X Tong, C Y Jiang et al. Development of stable, narrow spectral line-width, fiber delivered laser source for spin exchange optical pumping. Appl Opt, 54, 5420(2015).

[5] W Fang, Y Fei, X Zhang et al. Subkilohertz linewidth reduction of a DFB diode laser using self-injection locking with a fiber Bragg grating Fabry-Perot cavity. Opt Express, 24, 17406(2016).

[6] H K Hisham, G A Mahdiraji, A F Abas et al. Linewidth optimization in fiber grating Fabry-Perot laser. Opt Eng, 53, 026107(2014).

[7] D P Liu, n C Chen, n L Qin et al. Study on linewidth characteristics of fiber grating external cavity semiconductor laser. Semicond Optoelectron, 37, 165(2016).

[8] C H Henry. Theory of the linewidth of semiconductor lasers. IEEE J Quantum Electron, 18, 259(1982).

[9] Y J Chai, H Y Zhang, B K Zhou. Line width performance and lysis of semiconductor lasers with strong feed back external cavity. Chin J Semicond, 16, 885(1995).

[10] B W Pan, L Q Yu, u D Lu et al. 20 kHz narrow linewidth fiber Bragg grating external cavity semiconductor laser. Chin J Lasers, 42, 49(2015).

[11] M Alalusi, P Brasil, S Lee et al. Low noise planar external cavity laser for interferometric fiber optic sensors. Proc SPIE, 7316(2009).

[12] V Vusirikala, S S Saini, R E Bartolo et al. Compact mode expanders using resonant coupling between a tapered active region and an underlying coupling waveguide. IEEE Photonics Technol Lett, 10, 203(1998).

[13] H Bissessur, C Graver, O L Gouezigou et al. Ridge laser with spot-size converter in a single epitaxial step for high coupling efficiency to single-mode fibers. IEEE Photonics Technol Lett, 10, 1235(1998).

[14] T Tsuchizawa, T Watanabe, K Yamada et al. Microphotonics devices based on silicon microfabrication technology. IEEE J Sel Top Quantum Electron, 11, 232(2005).

[15] R A Soref, J Schmidthen, K Petermann. Large single-mode rib waveguide in GeSi and Si-on-SiO₂. IEEE J Quantum Electron, 27, 1971(1991).

[16] A G Richman, G T Ree, F Namavar. Silicon-on-insulator optical rib waveguide loss and mode characteristics. J Lightwave Technol, 12, 1771(1994).

[17] M Sumy, S Steffen, S Ralf et al. Geometrical tolerance of optical fiber and laser diode for passive alignment using LTCC technology. German Microwave Conference, 363(2015).

[18] S Romero-Garcia, B Marzban, F Merget et al. Edge Couplers with relaxed alignment tolerance for pick-and-place hybrid integration of III–V lasers with SOI waveguides. IEEE J Sel Top Quantum Electron, 20, 369(2014).

[19] P K Shen, C T Chen, C H Chang et al. Implementation of chip-level optical interconnect with laser and photodetector using SOI-based 3-D guided-wave path. IEEE Photonics J, 6, 1(2014).