一氧化氮退火对高温氧化SiC/SiO2界面特性的影响研究

本文研究了高温（1300℃）氧化并在一氧化氮（NO）气体中进行氧化后退火方法对4H-SiC 金属-氧化物-半导体（MOS）电容的SiC/SiO2界面特性的影响,主要通过SiC MOS的电容-电压(C-V)特性详细讨论了NO退火时间和温度与SiO2/SiC界面特性的相互关系. 结果表明在NO气体中进行氧化后退火可明显降低界面态密度,并且界面态密度随着温度和时间的增加会进一步降低。 同时,与常规1200℃及以下氧化温度相比,1300℃下热生长的氧化层具有更低的界面态密度且显著缩短了氧化时间,节约了生产成本。     

基于SiC基底的Y2O3/Al2O3堆栈MOS 电容的特性研究

通过在n型碳化硅(SiC)晶圆上用物理气相沉积法(PVD)和原子层沉积法(ALD)分别沉积 Y2O3介质和Al2O3，形成金属/Al2O3/Y2O3/SiC高k介质堆栈结构MOS电容，X射线光电子能谱(XPS)分析研究Al2O3/Y2O3堆栈结构氧化层介质之间以及氧化层与SiC晶圆之间的相互扩散和反应关系，研究不同金属电极MOS电容的C-V特性，Ni电极MOS电容具有良好的稳定性，对介质层的相对介电常数影响最小，Mg电极MOS电容的理想平带电压最小，同时氧化层陷阱密度最小，随着C-V测试频率的降低，氧化层电容Cox逐渐增加Al2O3/Y2O3介质层的相对介电常数逐渐增大，等效氧化层厚度(EOT)减小，平带电容电压减小。     

Characterization of the effects of nitrogen and hydrogen passivation on SiO2/4H-SiC interface by low temperature conductance measurements

In this work we investigate the effects of NO annealing and forming gas (FG) an-nealing on the electrical properties of SiO2/SiC interface by low-temperature con-ductance measurements. With nitrogen passivation, the density of interface states (DIT) is significantly reduced in the entire energy range, and the shift of flatband voltage, ΔVFB, is effectively suppressed to less than 0.4 V. However, very fast states are ob-served after NO annealing and the response frequencies are higher than 1 MHz at room temperature. After additional FG annealing, the DIT and ΔVFB are further re-duced. The values of the DIT decrease to less than 1011 cm-2eV-1 for the energy range of EC-ET≥0.4 eV. It is suggested that the fast states in shallow energy levels origi-nated from the N atoms accumulating at the interface by NO annealing. Though FG annealing has a limited effect on these shallow traps, hydrogen can terminate the re-sidual Si and C dangling bonds corresponding to traps at deep energy levels and im-prove the interface quality further. It is indicated that NO annealing in conjunction with FG annealing will be a better post-oxidation process method for high perfor-mance SiC MOSFETs.     

SiO2/4H-SiC界面氮化退火

通过1 300℃高温干氧热氧化法在n型4H-SiC外延片上生长了厚度为60 nm的SiO2栅氧化层.为了开发适合于生长低界面态密度和高沟道载流子迁移率的SiC MOSFET器件产品的栅极氧化层退火条件,研究了不同退火条件下的SiO2/SiC界面电学特性参数.制作了MOS电容和横向MOSFET器件,通过表征SiO2栅氧化层C-V特性和MOSFET器件I-V特性,提取平带电压、C-V磁滞电压、SiO2/SiC界面态密度和载流子沟道迁移率等电学参数.实验结果表明,干氧氧化形成SiO2栅氧化层后,在1 300℃通入N2退火30 min,随后在相同温度下进行NO退火120 min,为最佳栅极氧化层退火条件,此时,SiO2/SiC界面态密度能够降低至2.07×1012 cm-2·eV-1@0.2 eV,SiC MOSFET沟道载流子迁移率达到17 cm2·V-1·s-1.