Impact of Stacking Faults and Domain Boundaries on the Electronic Transport in Cubic Silicon Carbide Probed by Conductive Atomic Force Microscopy

材料科学 碳化硅 堆积 导电原子力显微镜 导电体 原子力显微镜 凝聚态物理 纳米技术 化学物理 结晶学 光电子学 复合材料 核磁共振 化学 物理
作者
Filippo Giannazzo,Giuseppe Greco,Salvatore Di Franco,Patrick Fiorenza,Ioannis Deretzis,Antonino La Magna,Corrado Bongiorno,Massimo Zimbone,Francesco La Via,Marcin Zieliński,Fabrizio Roccaforte
出处
期刊:Advanced electronic materials [Wiley]
卷期号:6 (2) 被引量:14
标识
DOI:10.1002/aelm.201901171
摘要

Abstract In spite of its great promise for energy‐efficient power conversion, the electronic quality of cubic silicon carbide (3C‐SiC) on silicon is currently limited by the presence of a variety of extended defects in the heteroepitaxial material. However, the specific role of the different defects on the electronic transport is still under debate. A macro‐ and nanoscale characterization of Schottky contacts on 3C‐SiC/Si is carried out to elucidate the impact of the anti‐phase boundaries (APBs) and stacking faults (SFs) on the forward and reverse current–voltage characteristics of these devices. Current mapping of 3C‐SiC by conductive atomic force microscopy directly shows the role of APBs as the main defects responsible of the reverse bias leakage, while both APBs and SFs are shown to work as preferential current paths under forward polarization. Distinct differences between these two types of defects are also confirmed by electronic transport simulations of a front‐to‐back contacted SF and APB. These experimental and simulation results provide a picture of the role played by different types of extended defects on the electrical transport in vertical or quasi‐vertical devices based on 3C‐SiC/Si, and can serve as a guide for improving material quality by defects engineering.

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