The research on influence factors of high power GaN blue diode laser (LD) performance degradation
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摘要: 高功率GaN基蓝光二极管激光器在工业加工、铜材料焊接、3D打印、水下激光通信等技术领域有着广泛的应用前景。蓝光二极管激光芯片COS单元器件具有热阻低和尺寸小的优点,但是该器件存在可靠性较低的问题,导致其在工业化应用中受到一定限制,因此对其性能退化因素进行深入研究。基于光学显微技术、扫描电子显微表征和能谱分析手段对经过长时老化考核后器件的性能退化因素进行分析研究。实验研究和分析表明,GaN基体材料缺陷、腔面多余物沉积和光化学腐蚀是导致蓝光二极管激光芯片性能退化的主因,同时良好的气密性封装可提高二极管激光芯片的可靠性。
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关键词:
- GaN蓝光二极管激光器 /
- 性能退化 /
- 二极管激光器封装 /
- 气密封 /
- 高功率
Abstract:Background High power GaN-based blue diode lasers have wide application prospects in industrial processing, copper material welding, 3D printing, underwater laser communication and other technical fields. The Chip On Submount (COS unit) packaged in the heat sink is a kind of single component that can be applied to the fabrication of high power GaN-based blue diode lasers. The device has the advantages of low thermal resistance and small size.Purpose However, due to the low reliability of this device, the industrial application of this COS single component in high power GaN-based blue diode lasers is still limited to a certain extent, and its performance degradation factors need to be studied.Methods In this paper, based on the optical microscopy、scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) the degradation factors of high power blue light COS components were studied.Results Finally, the experimental study and analysis show that the performance degradation factors of blue light diode laser chip are mainly related to GaN matrix material defects, cavity surface surplus deposition and photochemical corrosion factors, and through experiments, it is compared that high power blue light COS single component can improve its reliability by hermetic packaging and provide a reference for the subsequent engineering application of high power blue COS units.Conclusions Finally, experimental research and analysis indicate that the performance degradation factors of high-power blue laser diodes (LDs) are primarily related to defects in the GaN substrate material, foreign matter deposition on the cavity surface, and photochemical corrosion factors. Comparative experiments further reveal that the threshold current growth rate of LDs with gas sealing (~0.14 mA/h) is lower than that of non-gas-sealed LDs (~0.27 mA/h). This demonstrates that gas-sealed packaging of high-power blue LD COS unit devices can enhance their reliability.-
Key words:
- GaN blue diode laser /
- performance degradation /
- diode laser packging /
- hermetic packaging /
- high power
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图 3 LD在长时老化考核前后的输出波长变化统计
Figure 3. The wavelength statistics of the hermetic packaged LD and non-hermetic packaged LD
图 4 非气密封LD前腔面。(a)未老化,(b)老化100小时后,(c)老化
1100 小时后Figure 4. The images of front cavity surface of the non-hermetic packaged COS
图 5 气密封LD长时老化考核后的前腔面
Figure 5. The images of front cavity surface of the hermetic packaged COS after 1100h aging
图 6 非气密封LD前腔面附着物SEM和EDS分析
Figure 6. SEM and EDS analysis of the front cavity surface of a non-hermetic LD
图 7 非气密封LD老化考核后的SEM和EDS
Figure 7. SEM and EDS analysis of the front cavity surface of non-hermetic LD after 1100h aging
表 1 EDS各元素占比
Table 1. The contents of the elements
Elt. Atomic/% Atomic Ratio Conc./(wt.%) N 0.000 0.0000 0.000 O 35.256 1.0000 16.862 Al 23.464 0.6655 18.925 Si 25.972 0.7367 21.805 Ga 12.422 0.3523 25.890 Sn 0.205 0.0058 0.727 Au 2.682 0.0761 15.792 Total 100.000 — 100.000 
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