| Literature DB >> 27642767 |
Gang Niu1,2, Giovanni Capellini2,3, Fariba Hatami4, Antonio Di Bartolomeo5, Tore Niermann6, Emad Hameed Hussein4, Markus Andreas Schubert2, Hans-Michael Krause2, Peter Zaumseil2, Oliver Skibitzki2, Grzegorz Lupina2, William Ted Masselink4, Michael Lehmann6, Ya-Hong Xie7, Thomas Schroeder2,8.
Abstract
The epitaxial integration of highly heterogeneous material systems with silicon (Si) is a central topic in (opto-)electronics owing to device applications. InP could open new avenues for the realization of novel devices such as high-mobility transistors in next-generation CMOS or efficient lasers in Si photonics circuitry. However, the InP/Si heteroepitaxy is highly challenging due to the lattice (∼8%), thermal expansion mismatch (∼84%), and the different lattice symmetries. Here, we demonstrate the growth of InP nanocrystals showing high structural quality and excellent optoelectronic properties on Si. Our CMOS-compatible innovative approach exploits the selective epitaxy of InP nanocrystals on Si nanometric seeds obtained by the opening of lattice-arranged Si nanotips embedded in a SiO2 matrix. A graphene/InP/Si-tip heterostructure was realized on obtained materials, revealing rectifying behavior and promising photodetection. This work presents a significant advance toward the monolithic integration of graphene/III-V based hybrid devices onto the mainstream Si technology platform.Entities:
Keywords: III−V compounds; graphene; monolithic integration; nanoheteroepitaxy; rectification
Year: 2016 PMID: 27642767 DOI: 10.1021/acsami.6b09592
Source DB: PubMed Journal: ACS Appl Mater Interfaces ISSN: 1944-8244 Impact factor: 9.229