温度和应力对InGaP/GaAs异质结光电晶体管的影响

Journal of Science and Technology: Issue on Information and Communications Technology Pub Date : 2021-06-29 DOI:10.31130/ict-ud.2021.112

Phuc Hong Than, Tran Thi Tra Vinh, L. Hạnh, Than Quang Tho, N. V. A. Quang, Tran The Son

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引用次数: 0

摘要

虽然电应力和温度对InGaP/GaAs异质结双极晶体管(HBTs)性能的影响已经被广泛研究和报道，但文献中很少或没有关于InGaP/GaAs异质结光电晶体管(HPTs)的报道。在本文中，我们讨论了InGaP/GaAs hts在电应力前后的温度依赖特性，并评估了发射脊钝化的有效性，发现该钝化可以有效地防止InGaP/GaAs hts在更高温度或电应力后降解。即使在较高的温度下，发射架钝化也能有效地保持较高的光学增益。通过将集电极电流保持在60 mA并持续15分钟，对hpt施加电应力。由于作为电应力的集电极电流密度为24 A/cm2，远小于应力测试中通常给予较小hpt的应力，因此在室温下给予时未观察到光学增益的下降。然而，当它在420 K时，在任何温度下都观察到电流增益和光增益的显著下降。然而，发现发射架钝化可以有效地减少电流增益和光增益的下降。

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Effects of Temperature and Stress on the InGaP/GaAs Heterojunction Phototransistor

Although the effects of electrical stress and temperature on the performance of the InGaP/GaAs heterojunction bipolar transistors (HBTs) have been widely studied and reported, little or none was reported for the InGaP/GaAs heterojunction phototransistors (HPTs) in the literature. In this paper, we discuss the temperature-dependent characteristic of InGaP/GaAs HPTs before and after electrical stress and assess the effectiveness of the emitter-ledge passivation, which was found to effectively keep the InGaP/GaAs HBTs from degrading at higher temperature or after an electrical stress. The emitter-ledge passivation is also effective keeping a higher optical gain even at higher temperature. An electrical stress was given to the HPTs by keeping the collector current at 60 mA for 15 min. Since the collector current density as an electrical stress is 24 A/cm2 and much smaller than the stress usually given to smaller HBTs for the stress test, the decreased optical gain was not observed when it was given at room temperature. However, when it was given at 420 K, significant decreases of the current gain and optical gain were observed at any temperature. Nevertheless, the emitter-ledge passivation was found effective in minimizing the decreases of the current gain and optical gain.

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Journal of Science and Technology: Issue on Information and Communications Technology

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