微通道冷却高功率二极管激光阵列的热行为

Dihai Wu, Pu Zhang, Zhiqiang Nie, Lingling Xiong, Yunfei Song, Qiwen Zhu, Yao Lu, Yifan Dang, Xingsheng Liu
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引用次数: 3

摘要

在有源区产生的热量导致结温过高,这对大功率二极管激光阵列的电学和光学性能、可靠性和寿命都有显著影响。了解器件的热行为对改进器件性能具有重要意义。与传导冷却技术相比,封装在微通道散热器上的二极管激光阵列具有更强的散热能力,从而提供更高的输出功率,保证高可靠性。本文采用基于有限元法和计算流体力学的数值方法研究了微通道冷却高功率二极管激光器阵列的热特性。详细研究了连续波模式下不同水流速率下装置的静态和瞬态热行为。揭示了激光芯片、焊料界面和MCC散热器对热阻的影响。分析了热阻与水流速率的关系。推导了与活性区、铜散热器和铜/水界面有关的三种不同加热过程的热时间常数。采用独立发射极分析方法,通过热串扰讨论了半导体激光器阵列结温的非均匀性。了解二极管激光阵列中的热现象可以为优化操作条件、MCC散热器结构和封装架构提供有用的指导,以提高性能和可靠性。
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Thermal behavior of microchannel cooled high power diode laser arrays
Heat generation in the active region leads to high junction temperature that significantly affects electrical and optical properties, reliability and lifetime of high power diode laser arrays. It is of great importance to understand the thermal behavior to improve the devices. Compared to conduction cooling techniques, diode laser arrays packaged on microchannel heat sinks have superior capability to dissipate the large amount of heat so as to deliver higher output power and ensure high reliability. In this paper, numerical approach based on finite element method (FEM) and computational fluid dynamics (CFD) was employed to investigate thermal properties of microchannel cooled (MCC) high power diode laser arrays. The static and transient thermal behavior of the devices operated in continuous wave (CW) mode at different water flow rates have been studied in detail. The thermal resistance contributed from the laser chip, solder interface and MCC heat sink was revealed. The correlation between thermal resistance and water flow rate was analyzed. The thermal time constants were derived to characterize the three distinct heating processes related to active region, copper heat sink and copper/water interface. Non-uniformity of junction temperature across the diode laser array was discussed by thermal crosstalk employing the independent emitter analysis. Understanding thermal phenomena in diode laser arrays could offer useful guidelines in optimizing the operating conditions, MCC heat sink structures and packaging architectures for enhanced performance and reliability.
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