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Charge Ordering in K 4 Fe 3 F 12 from a First Principles Study
Author(s) -
Liu Shanshan,
Xu Yuanhui,
Qu Nianrui,
Zhang Yizhi,
Wang Jing,
Sun Keju,
Hao Xianfeng
Publication year - 2017
Publication title -
chemistryselect
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.437
H-Index - 34
ISSN - 2365-6549
DOI - 10.1002/slct.201601472
Subject(s) - charge ordering , antiferromagnetism , charge (physics) , condensed matter physics , coulomb , spins , mott insulator , ground state , electronic structure , electron , physics , materials science , chemistry , atomic physics , quantum mechanics
First‐principles calculations based on the generalized gradient approximation plus the on‐site Coulomb repulsion (GGA+U) approach, as implemented in the VASP code, have been used to investigate the structural, electronic as well as magnetic properties of a new charge‐ordered iron fluoride material, K 4 (Fe 2+ )(Fe 3+ ) 2 F 12 , within a layered perovskite‐related structure. Our results established that K 4 Fe 3 F 12 is a Mott‐Hubbard insulator, and adopts a magnetically ground state where the Fe 2+ and Fe 3+ spins are arranged in an approximately antiparallel manner to each other, in agreement with the experimental observations. Although the total 3d charge disproportion is rather small, an order parameter, defined as the difference between the dz 2 orbital occupations of the the Fe 3+ and Fe 2+ cations, provides explicit evidence on the charge ordering. Strong hybridization between F 2 p and Fe 3 d states leads into the nearly complete loss of the separation between the total charges at the Fe 2+ and Fe 3+ cations. Furthermore, the unique occupation of the dz 2 orbital is responsible for the stability of the antiferromagnetic spin ordering and the charge ordering pattern.