Invariant-molecular-dynamics study of the diamond-to-beta-Sn transition in Si under hydrostatic and uniaxial compressions
We study the diamond-to-beta-Sn structural phase transition in Si under hydrostatic and uniaxial compressions using an invariant-molecular-dynamics approach based on an empirical potential model. Isobaric molecular-dynamics simulations show that the diamond-cubic lattice under hydrostatic compression becomes unstable against tetragonal shear deformation into the beta-Sn phase at 60 GPa, which is much higher than experimental values. This very high pressure is attributed to the fact that a perfect single crystal is superpressured due to the activation barrier, well above the transition pressure where the two structures coexist, in analogy to isobaric superheating in molecular-dynamics simulations. Under uniaxial compression, the enthalpy barrier for the diamond-to-beta-Sn transition is found to be effectively reduced.
- Publisher
- AMERICAN PHYSICAL SOC
- Issue Date
- 1997-03
- Language
- English
- Article Type
- Article
- Keywords
STRUCTURAL PHASE-TRANSITIONS; HIGH-PRESSURE; CRYSTAL STABILITY; LATTICE-DYNAMICS; SILICON; ENERGY; TRANSFORMATIONS; SIMULATIONS; TEMPERATURE; SYSTEMS
- Citation
PHYSICAL REVIEW B, v.55, no.9, pp.5689 - 5693
- ISSN
- 0163-1829
- Appears in Collection
- PH-Journal Papers(저널논문)
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