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Metallization and superconductivity of BeH
2
under high pressure
Ziwei Wang
, Yansun Yao
,
Li Zhu
, Hanyu Liu
, Toshiaki Iitaka
, Hui Wang
, Yanming Ma
Research output
:
Contribution to journal
›
Article
›
peer-review
55
Link opens in a new tab
Scopus citations
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2
under high pressure'. Together they form a unique fingerprint.
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Keyphrases
Phase Transition
100%
Superconductivity
100%
High Pressure
100%
Metallization
100%
Electron-phonon Coupling
100%
Three-dimensional (3D)
50%
Direct Band Gap
50%
Band Gap
50%
Electronic States
50%
Pressure-induced
50%
Transition Metal Dichalcogenides
50%
Superconducting Transition Temperature
50%
Metallic State
50%
Search Methods
50%
Stacking Sequence
50%
Structural Transformation
50%
Isostructural
50%
Structure Search
50%
Polyhedron
50%
Edge-sharing
50%
Pressure Rise
50%
Delocalized Electrons
50%
Van Der Waals Force
50%
Coupled Calculation
50%
Linear Response Theory
50%
Density Functional Theory (DFT) Calculations
50%
Wide Pressure Range
50%
Pressure-induced Metallization
50%
Gap Closure
50%
Engineering
Superconductivity
100%
Metallizations
100%
Band Gap
100%
Covalent
50%
Transition Metal Dichalcogenide
50%
Pressure Increase
50%
Pressure Range
50%
Direction Perpendicular
50%
Linear Response
50%
Induced Metallization
50%
Delocalized Electron
50%
Electronic State
50%
Crystal Structure
50%
Chemistry
Superconductivity
100%
Band Gap
100%
Phonon
100%
First Principle
50%
Electronic State
50%
Crystal Structure
50%
Van Der Waals Force
50%
Cmcm
50%
Ibam
50%
Transition Metal
50%
Physics
Superconductivity
100%
Phonon
100%
Metallizing
100%
First Principle
50%
Transition Metal Dichalcogenide
50%
Stacking
50%
Crystal Structure
50%
Material Science
Superconductivity
100%
Density
50%
Transition Metal Dichalcogenide
50%
Crystal Structure
50%