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    Journals >Opto-Electronic Engineering >Volume 51 >Issue 4 >Page 230302-1 > Article
    • Opto-Electronic Engineering
    • Vol. 51, Issue 4, 230302-1 (2024)
    Research on the beam combining technique of a 350 W blue semiconductor laser for urological applications
    Haoxuan Zheng, Xuanyu Hu, Yi Zheng, Changcheng Duan..., Yu Xiao, Gang Xu and Xiahui Tang*|Show fewer author(s)
    Author Affiliations
  • School of Optical and Electronic Information, Huazhong University of Science and Technology, Wuhan, Hubei 430074, China
    • show less
    DOI: 10.12086/oee.2024.230302 Cite this Article
    Haoxuan Zheng, Xuanyu Hu, Yi Zheng, Changcheng Duan, Yu Xiao, Gang Xu, Xiahui Tang. Research on the beam combining technique of a 350 W blue semiconductor laser for urological applications[J]. Opto-Electronic Engineering, 2024, 51(4): 230302-1 Copy Citation Text show less
    References

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    [2] H H Min, G H Liu, X J Zhai et al. Research progress of single-doped holmium solid-state lasers. Laser Optoelectron Prog, 59, 2100002(2022).

    [3] Y S Sun, Q D Duanmu, P Lin et al. 1.6 μm band mode-locked fiber laser. Chin Opt, 14, 1387-1394(2021).

    [4] A M Elshal, M A Elkoushy, A R El-Nahas et al. GreenLightTM laser (XPS) photoselective vapo-enucleation versus holmium laser enucleation of the prostate for the treatment of symptomatic benign prostatic hyperplasia: a randomized controlled study. J Urol, 193, 927-934(2015).

    [5] V Misrai, S Kerever, V Phe et al. Direct comparison of GreenLight Laser XPS photoselective prostate vaporization and GreenLight laser en bloc enucleation of the prostate in enlarged glands greater than 80 ml: a study of 120 patients. J Urol, 195, 1027-1032(2016).

    [6] A H Aldoukhi, W W Roberts, T L Hall et al. Watch your distance: the role of laser fiber working distance on fragmentation when altering pulse width or modulation. J Endourol, 33, 120-126(2019).

    [7] M M Elhilali, S Badaan, A Ibrahim et al. Use of the moses technology to improve holmium laser lithotripsy outcomes: a preclinical study. J Endourol, 31, 598-604(2017).

    [8] B Winship, D Wollin, E Carlos et al. Dusting efficiency of the moses holmium laser: an automated in vitro assessment. J Endourol, 32, 1131-1135(2018).

    [9] A G Martov, D V Ergakov, M A Guseinov et al. Initial experience in clinical application of thulium laser contact lithotripsy for transurethral treatment of urolithiasis. Urologiia, 112-120(2018).

    [10] Ø Ulvik, M S Æsøy, P Juliebø-Jones et al. Thulium fibre laser versus holmium: YAG for ureteroscopic lithotripsy: outcomes from a prospective randomised clinical trial. Eur Urol, 82, 73-79(2022).

    [11] D L Jiang, Z Yang, G X Liu et al. A novel 450-nm blue laser system for surgical applications: efficacy of specific laser-tissue interactions in bladder soft tissue. Lasers Med Sci, 34, 807-813(2019).

    [12] X F Xu, D L Jiang, G X Liu et al. A novel 450 nm semiconductor blue laser system for application in colon endoscopic surgery: an ex vivo study of laser-tissue interactions. Photobiomodul Photomed Laser Surg, 37, 25-30(2019).

    [13] H Yu, X H Ma, Y G Zou et al. Beam shaping design for fiber-coupled laser-diode system based on a building block trapezoid prism. Opt Laser Technol, 109, 366-369(2019).

    [14] G Y Lin, P F Zhao, Z Y Dong et al. Beam-shaping technique for fiber-coupled diode laser system by homogenizing the beam quality of two laser diode stacks. Opt Laser Technol, 123, 105919(2020).

    [15] X C Lin, G Y Lin, P F Zhao et al. Generation of high brightness diode laser by using spectral and polarization beam combination. Opt Laser Technol, 116, 219-223(2019).

    [16] J Y Tian, J Zhang, H Y Peng et al. High power diode laser source with a transmission grating for two spectral beam combining. Optik, 192, 162918(2019).

    [17] B Liu. Research on high-power wavelength locking external cavity diode laser array and device development(2021). https://doi.org/10.27605/d.cnki.gkxgs.2021.000009

    [18] Z L Wang, S Drovs, A Segref et al. Fiber coupled diode laser beam parameter product calculation and rules for optimized design, 86-94(2011). https://doi.org/10.1117/12.875386

    [19] R Diehl. High-power diode lasers: fundamentals, technology, applications: with contributions by numerous experts(2000). https://doi.org/10.1007/3-540-47852-3

    [20] M Haas, S Rauch, S Nagel et al. Beam quality deterioration in dense wavelength beam-combined broad-area diode lasers. IEEE J Quantum Electron, 53, 2600111(2017).

    [21] Q Xu. The beam propagation characteristics of semiconductor lasers(2007).

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    Haoxuan Zheng, Xuanyu Hu, Yi Zheng, Changcheng Duan, Yu Xiao, Gang Xu, Xiahui Tang. Research on the beam combining technique of a 350 W blue semiconductor laser for urological applications[J]. Opto-Electronic Engineering, 2024, 51(4): 230302-1
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