摘要High-pressure Raman studies at room temperature are performed on CCl4 up to 13GPa. The Raman bands of the internal modes (v2, v4 and v1) show entirely positive pressure dependence. The slopes dω/dP of the internal modes exhibit two sudden changes at 0.73GPa and 7.13GPa, respectively. A new lower frequency mode (225cm-1) appears at 3.03GPa, and the splitting of v2, ν3 and v4 occurs at about 7.13GPa. Moreover, Raman spectra of Fermi resonance show that the relative position of the v1 + v4 combination and the ν3 fundamental firstly interchanges corresponding to that at ambient pressure, then the v1 +v4 combination disappears in the gradual process of compression. It is indicated that the pressure-induced phase transition from CCl4 II to CCl4 III occurs at 0.73GPa, and CCl4 III undergoes a transition to CCl4 IV below 3.03GPa. Further CCl4 IV transforms in a new high-pressure phase at about 7.13GPa, and the symmetry of the new high-pressure phase is lower than that of CCl4 IV. All the transitions are reversible during decompression.
Abstract:High-pressure Raman studies at room temperature are performed on CCl4 up to 13GPa. The Raman bands of the internal modes (v2, v4 and v1) show entirely positive pressure dependence. The slopes dω/dP of the internal modes exhibit two sudden changes at 0.73GPa and 7.13GPa, respectively. A new lower frequency mode (225cm-1) appears at 3.03GPa, and the splitting of v2, ν3 and v4 occurs at about 7.13GPa. Moreover, Raman spectra of Fermi resonance show that the relative position of the v1 + v4 combination and the ν3 fundamental firstly interchanges corresponding to that at ambient pressure, then the v1 +v4 combination disappears in the gradual process of compression. It is indicated that the pressure-induced phase transition from CCl4 II to CCl4 III occurs at 0.73GPa, and CCl4 III undergoes a transition to CCl4 IV below 3.03GPa. Further CCl4 IV transforms in a new high-pressure phase at about 7.13GPa, and the symmetry of the new high-pressure phase is lower than that of CCl4 IV. All the transitions are reversible during decompression.
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2009, Vol. 26 
