Bond deformation paths and electronic instabilities of ultraincompressible transition metal diborides: Case study of OsB2and IrB2

R. F. Zhang; D. Legut; X. D. Wen; S. Veprek; K. Rajan; T. Lookman; H. K. Mao; Y. S. Zhao

doi:10.1103/PhysRevB.90.094115

Bond deformation paths and electronic instabilities of ultraincompressible transition metal diborides: Case study of OsB₂and IrB₂

R. F. Zhang^*
, D. Legut
, X. D. Wen
, S. Veprek
, K. Rajan
, T. Lookman
, H. K. Mao
, Y. S. Zhao

^*Corresponding author for this work

School of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

19 Scopus citations

Abstract

The energetically most stable orthorhombic structure of OsB₂and IrB₂is dynamically stable for OsB₂but unstable for IrB2. Both diborides have substantially lower shear strength in their easy slip systems than their metal counterparts. This is attributed to an easy sliding facilitated by out-of-plane weakening of metallic Os-Os bonds in OsB₂and by an in-plane bond splitting instability in IrB₂. A much higher shear resistance of Os-B and B-B bonds than Os-Os ones is found, suggesting that the strengthened Os-B and B-B bonds are responsible for hardness enhancement in OsB₂. In contrast, an in-plane electronic instability in IrB₂limits its strength. The electronic structure of deformed diborides suggests that the electronic instabilities of 5d orbitals are their origin of different bond deformation paths. Neither IrB₂nor OsB₂can be intrinsically superhard.

Original language	English
Article number	094115
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	90
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevB.90.094115
State	Published - 26 Sep 2014

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title = "Bond deformation paths and electronic instabilities of ultraincompressible transition metal diborides: Case study of OsB2and IrB2",

abstract = "The energetically most stable orthorhombic structure of OsB2and IrB2is dynamically stable for OsB2but unstable for IrB2. Both diborides have substantially lower shear strength in their easy slip systems than their metal counterparts. This is attributed to an easy sliding facilitated by out-of-plane weakening of metallic Os-Os bonds in OsB2and by an in-plane bond splitting instability in IrB2. A much higher shear resistance of Os-B and B-B bonds than Os-Os ones is found, suggesting that the strengthened Os-B and B-B bonds are responsible for hardness enhancement in OsB2. In contrast, an in-plane electronic instability in IrB2limits its strength. The electronic structure of deformed diborides suggests that the electronic instabilities of 5d orbitals are their origin of different bond deformation paths. Neither IrB2nor OsB2can be intrinsically superhard.",

author = "Zhang, \{R. F.\} and D. Legut and Wen, \{X. D.\} and S. Veprek and K. Rajan and T. Lookman and Mao, \{H. K.\} and Zhao, \{Y. S.\}",

note = "Publisher Copyright: {\textcopyright} 2014 American Physical Society.",

year = "2014",

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day = "26",

doi = "10.1103/PhysRevB.90.094115",

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TY - JOUR

T1 - Bond deformation paths and electronic instabilities of ultraincompressible transition metal diborides

T2 - Case study of OsB2and IrB2

AU - Zhang, R. F.

AU - Legut, D.

AU - Wen, X. D.

AU - Veprek, S.

AU - Rajan, K.

AU - Lookman, T.

AU - Mao, H. K.

AU - Zhao, Y. S.

PY - 2014/9/26

Y1 - 2014/9/26

N2 - The energetically most stable orthorhombic structure of OsB2and IrB2is dynamically stable for OsB2but unstable for IrB2. Both diborides have substantially lower shear strength in their easy slip systems than their metal counterparts. This is attributed to an easy sliding facilitated by out-of-plane weakening of metallic Os-Os bonds in OsB2and by an in-plane bond splitting instability in IrB2. A much higher shear resistance of Os-B and B-B bonds than Os-Os ones is found, suggesting that the strengthened Os-B and B-B bonds are responsible for hardness enhancement in OsB2. In contrast, an in-plane electronic instability in IrB2limits its strength. The electronic structure of deformed diborides suggests that the electronic instabilities of 5d orbitals are their origin of different bond deformation paths. Neither IrB2nor OsB2can be intrinsically superhard.

AB - The energetically most stable orthorhombic structure of OsB2and IrB2is dynamically stable for OsB2but unstable for IrB2. Both diborides have substantially lower shear strength in their easy slip systems than their metal counterparts. This is attributed to an easy sliding facilitated by out-of-plane weakening of metallic Os-Os bonds in OsB2and by an in-plane bond splitting instability in IrB2. A much higher shear resistance of Os-B and B-B bonds than Os-Os ones is found, suggesting that the strengthened Os-B and B-B bonds are responsible for hardness enhancement in OsB2. In contrast, an in-plane electronic instability in IrB2limits its strength. The electronic structure of deformed diborides suggests that the electronic instabilities of 5d orbitals are their origin of different bond deformation paths. Neither IrB2nor OsB2can be intrinsically superhard.

UR - https://www.scopus.com/pages/publications/84907462285

U2 - 10.1103/PhysRevB.90.094115

DO - 10.1103/PhysRevB.90.094115

M3 - 文章

AN - SCOPUS:84907462285

SN - 1098-0121

VL - 90

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 9

M1 - 094115

ER -

Bond deformation paths and electronic instabilities of ultraincompressible transition metal diborides: Case study of OsB₂and IrB₂

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