Open AccessMagnetite Fe3O4 (111) Surfaces: Impact of Defects on Structure, Stability, and Electronic Properties
Author(s) -
JungHyun Noh,
Osman I. Osman,
Saadullah G. Aziz,
Paul Winget,
JeanLuc Brédas
Publication year - 2015
Publication title -
chemistry of materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.741
H-Index - 375
eISSN - 1520-5002
pISSN - 0897-4756
DOI - 10.1021/acs.chemmater.5b02885
Subject(s) - spintronics , magnetite , density functional theory , electronic structure , materials science , fermi level , chemical physics , nanotechnology , electronics , chemical stability , ferromagnetism , condensed matter physics , chemistry , computational chemistry , physics , metallurgy , organic chemistry , quantum mechanics , electron
We present a comprehensive investigation, via first-principles density functional theory (DFT) calculations, of various surface terminations of magnetite, Fe3O4 (111), a major iron oxide which has also a number of applications in electronics and spintronics. We compare the thermodynamic stability and electronic structure among the different surfaces terminations. Interestingly, we find that surfaces modified with point defects and adatoms can be more stable than bulk-like terminations. These surfaces show different surface chemistry, electronic structures and distinctive spin polarization features near the Fermi level from those previously considered in the literature. Our studies provide an atomic level insight for magnetite surfaces, which is a necessary step to understanding their interfaces with organic layers in OLED and spintronic devices
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