Anomalous behavior of the Madelung constant and I–Fe–I bonding angle at high-pressure induced structural phase transition of FeI2

Anomalous behavior of the Madelung constant and I–Fe–I bonding angle at high-pressure induced structural phase transition of FeI2

This study is devoted to theoretical analysis of the high-pressure experimental results available in literature that are associated with the structural phase transition of FeI2 in the pressure variation range up to ≈20 GPa. To establish the dependence of the interatomic interaction potentials of FeI...

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Bibliographic Details
Published in:Materials chemistry and physics Vol. 239; p. 122315
Main Author: Harutyunyan, V.S.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 01-01-2020
Elsevier BV
Subjects:
Bonding angle
Bonding strength
Destabilization
High pressure
Iron diiodide
Lattice parameters
Layered compounds
Madelung constant
Phase transitions
Pressure dependence
Structural phase transition
The Madelung constant
Iron diiodide
The Madelung constant
Layered compounds
Bonding angle
High pressure
Structural phase transition
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Summary:This study is devoted to theoretical analysis of the high-pressure experimental results available in literature that are associated with the structural phase transition of FeI2 in the pressure variation range up to ≈20 GPa. To establish the dependence of the interatomic interaction potentials of FeI2 on the pressure, theoretical relationships connecting the Madelung constant with the pressure-dependent lattice parameters, ionicity parameter, and I–Fe–I bonding angle are obtained. A strong correlation is revealed between the Madelung constant, ionicity parameter, and the bonding angle in their dependences on pressure. As a result of this correlation, with increase of pressure the Coulomb energy, which depends on the Madelung constant and ionicity parameter (i.e., ionic partial charges), tends to decrease, whereas the covalent energy dependent on the bonding angle exhibits a trend to increase. It is found that at the pressure of P = 16.9 GPa, the Madelung constant, ionicity parameter, and the bonding angle of the initial phase of FeI2 achieve their well-expressed minimum values. As a consequence, at above pressure the binding energy of FeI2 contributed by the Coulomb and covalent energies achieves its minimum value of 6.46 eV that results in structure destabilization and partial transition of the initial phase of the FeI2 to a new phase. It is concluded that, for FeI2 and compounds isostructural with this material, analysis of the pressure-dependent variation of the Madelung constant and bonding angle may be helpful in the prediction of possible structural phase transitions in high-pressure experimental investigations. [Display omitted] •With increase of pressure the ionic bonding in FeI2 transforms to covalent bonding.•The Madelung constant achieves a minimum at structural phase transition (SPT).•The I–Fe–I bonding angle that controls the covalent energy is also minimized at SPT.•The SPT at pressure P = 16.9 GPa results form minimization of the binding energy.•The mechanism of SPT is associated with the negative charge transfer from I to Fe ions.
ISSN:0254-0584
1879-3312
DOI:10.1016/j.matchemphys.2019.122315