AIN/GaN高电子迁移率晶体管的电压和温度依赖性降解

2018 International Integrated Reliability Workshop (IIRW) Pub Date : 2018-10-01 DOI:10.1109/IIRW.2018.8727092

T. Kemmer, M. Dammann, M. Baeumler, P. Brückner, H. Konstanzer, R. Quay, O. Ambacher

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引用次数: 2

摘要

我们研究了栅极长度分别为70 nm和100 nm的AIN/GaN高电子迁移率晶体管的电压和温度依赖性降解。被测器件在恒功耗为$4.5\displaystyle \frac {\mathrm {w}}{\mathrm {m}\mathrm {n}}$的半导通条件下施加直流应力约200h，或直到漏极饱和电流$I_{\mathrm {D}\mathrm {S}\mathrm {S}}$下降10%。为了检验是否可以确定像阿伦尼乌斯一样的温度加速度和额外的电压加速度，改变了通道温度和应力电压。在我们的测试中，这两个加速因素可以被确认，并被证明是相互依存的。Arrhenius拟合得到的活化能在0.80 ~ 1.12 eV之间。采用一种广义的Eyring方法来模拟温度和电压及其相互依赖性的联合加速度。

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Voltage- and Temperature-Dependent Degradation of AIN/GaN High Electron Mobility Transistors

We investigated the voltage- and temperature -dependent degradation of AIN/GaN high electron mobility transistors with gate lengths of 70 nm and 100 nm. The devices under test were dc stressed in semi-on-state conditions at constant power dissipation of $4.5\displaystyle \frac {\mathrm {w}}{\mathrm {m}\mathrm {n}}$ for approximately 200h or until the drain saturation current $I_{\mathrm {D}\mathrm {S}\mathrm {S}}$ dropped by 10 %. To examine whether a Arrhenius like temperature acceleration and additionally voltage acceleration can be ascertained, the channel temperature and stress voltage were varied. In our tests, both acceleration factors could be confirmed and are shown to be interdependent. Arrhenius fits resulted in activation energies between 0.80 eV and 1.12 eV. A generalized Eyring approach is used to model the combined acceleration by temperature and voltage as well as their interdependency.

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2018 International Integrated Reliability Workshop (IIRW)

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