6533b829fe1ef96bd12897e4

RESEARCH PRODUCT

High-pressure vibrational and optical study of Bi2Te3

Rosario VilaplanaE. Pérez-gonzálezJesus GonzalezJesus GonzalezCestmir DrasarOscar GomisVicente Muñoz-sanjoséAlfredo SeguraV. Marín-borrásAlfonso MuñozFrancisco Javier ManjónV. KucekPlácida Rodríguez-hernández

subject

DiffractionPhase transitionMaterials scienceCondensed matter physicsBand gapHydrostatic pressureCondensed Matter PhysicsElectronic Optical and Magnetic Materialssymbols.namesakeHysteresischemistry.chemical_compoundchemistryPhase (matter)symbolsBismuth tellurideRaman spectroscopy

description

We report an experimental and theoretical lattice dynamics study of bismuth telluride (Bi2Te 3 )u p to 23 GPa together with an experimental and theoretical study of the optical absorption and reflection up to 10 GPa. The indirect bandgap of the low-pressure rhombohedral (R-3m) phase (α-Bi2Te 3) was observed to decrease with pressure at a rate of − 6m eV/GPa. In regard to lattice dynamics, Raman-active modes of α-Bi2Te 3 were observed up to 7.4 GPa. The pressure dependence of their frequency and width provides evidence of the presence of an electronic-topological transition around 4.0 GPa. Above 7.4 GPa a phase transition is detected to the C2/m structure. On further increasing pressure two additional phase transitions, attributed to the C2/c and disordered bcc (Im-3m) phases, have been observed near 15.5 and 21.6 GPa in good agreement with the structures recently observed by means of x-ray diffraction at high pressures in Bi2Te 3. After release of pressure the sample reverts back to the original rhombohedral phase after considerable hysteresis. Raman- and IR-mode symmetries, frequencies, and pressure coefficients in the different phases are reported and discussed.

yearjournalcountryeditionlanguage
2011-09-09Physical Review B
https://doi.org/10.1103/physrevb.84.104112