English

Lattice-mismatched semiconductor heterostructures

Applied Physics 2018-12-27 v1

Abstract

Semiconductor heterostructure is a critical building block for modern semiconductor devices. However, forming semiconductor heterostructures of lattice-mismatch has been a great challenge for several decades. Epitaxial growth is infeasible to form abrupt heterostructures with large lattice-mismatch while mechanical-thermal bonding results in a high density of interface defects and therefore severely limits device applications. Here we show an ultra-thin oxide-interfaced approach for the successful formation of lattice-mismatched semiconductor heterostructures. Following the depiction of a theory on the role of interface oxide in forming the heterostructures, we describe experimental demonstrations of Ge/Si (diamond lattices), Si/GaAs (zinc blende lattice), GaAs/GaN (hexagon lattice), and Si/GaN heterostructures. Extraordinary electrical performances in terms of ideality factor, current on/off ratio, and reverse breakdown voltage are measured from p-n diodes fabricated from the four types of heterostructures, significantly outperforming diodes derived from other methods. Our demonstrations indicate the versatility of the ultra-thin-oxide-interface approach in forming lattice-mismatched heterostructures, open up a much larger possibility for material combinations for heterostructures, and pave the way toward broader applications in electronic and optoelectronic realms.

Keywords

Cite

@article{arxiv.1812.10225,
  title  = {Lattice-mismatched semiconductor heterostructures},
  author = {Dong Liu and Sang June Cho and Jung-Hun Seo and Kwangeun Kim and Munho Kim and Jian Shi and Xin Yin and Wonsik Choi and Chen Zhang and Jisoo Kim and Mohadeseh A. Baboli and Jeongpil Park and Jihye Bong and In-Kyu Lee and Jiarui Gong and Solomon Mikael and Jae Ha Ryu and Parsian K. Mohseni and Xiuling Li and Shaoqin Gong and Xudong Wang and Zhenqiang Ma},
  journal= {arXiv preprint arXiv:1812.10225},
  year   = {2018}
}

Comments

29 pages, 6 figures, 1 table. Supplementary Information not included

R2 v1 2026-06-23T06:56:05.385Z