Structural and vibrational properties of methane up to 71 GPa

Single-crystal synchrotron x-ray diffraction, Raman spectroscopy, and first principles calculations have been used to identify the structure of the high-pressure (HP) phase of molecular methane above 20 GPa up to 71 GPa at room temperature. The structure of the HP phase is trigonal R3, which can be represented as a distortion of the cubic phase B, previously documented at 7-15 GPa and confirmed here. The positions of hydrogen atoms in the HP phase have been obtained from first principles calculations, which also demonstrated the stability of this structure above 260 K at 25 GPa. The molecules occupy four different crystallographic sites in phase B and 11 sites in the HP phase, which result in splitting of molecular stretching modes detected in Raman spectroscopy and assigned here based on a good agreement with the Raman spectra calculated from the first principles. Our study points out to a single HP phase unlike up to three HP phases proposed previously based on the Raman spectroscopy results only.

Automated summary

The study identified the structure of the high-pressure phase of molecular methane using single-crystal synchrotron x-ray diffraction, Raman spectroscopy, and first principles calculations. It revealed the relationship between the high-pressure phase and the previously documented phase B, and determined the positions of hydrogen atoms through calculations. The study's findings differ from previous proposals of multiple high-pressure phases based solely on Raman spectroscopy results.