| Literature DB >> 26457875 |
Niccolo R C Corsini1, Yuanpeng Zhang2, William R Little2, Ali Karatutlu2,3, Osman Ersoy2, Peter D Haynes1, Carla Molteni4, Nicholas D M Hine5,6, Ignacio Hernandez7, Jesus Gonzalez7, Fernando Rodriguez7, Vadim V Brazhkin8, Andrei Sapelkin2.
Abstract
Over the last two decades, it has been demonstrated that size effects have significant consequences for the atomic arrangements and phase behavior of matter under extreme pressure. Furthermore, it has been shown that an understanding of how size affects critical pressure-temperature conditions provides vital guidance in the search for materials with novel properties. Here, we report on the remarkable behavior of small (under ~5 nm) matrix-free Ge nanoparticles under hydrostatic compression that is drastically different from both larger nanoparticles and bulk Ge. We discover that the application of pressure drives surface-induced amorphization leading to Ge-Ge bond overcompression and eventually to a polyamorphic semiconductor-to-metal transformation. A combination of spectroscopic techniques together with ab initio simulations were employed to reveal the details of the transformation mechanism into a new high density phase-amorphous metallic Ge.Entities:
Keywords: Ge nanoparticles; Raman; X-ray absorption; amorphization; density functional theory calculations; high pressure; phase transformation
Year: 2015 PMID: 26457875 DOI: 10.1021/acs.nanolett.5b02627
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189