Raman spectroscopy is one of the useful tool to get information of gas hydrate crystals. Natural gas hydrates in submarine/sublacustrine sediment mainly encage methane. Methane molecule is composed of carbon and hydrogen, and three kinds of isotopologues, ¹²CH₄, ¹³CH₄, and CH₃D exist in nature. Ozeki et al. (2018) first reported Raman spectra of CH₃D and CD₄ hydrates and compared with CH₄ (mainly ¹²CH₄) hydrate. We report Raman spectra of ¹³CH₄ hydrate and summarize Raman spectra of isotopologue methane hydrates.

¹³CH₄ hydrate sample was synthesized in a small pressure cell (volume: 5 mL). Fine ice powder (1g) was put in the pressure cell, and introduced appropriate amount of ¹³CH₄ (purity: 99.5%, Taiyo-Nissan). ¹³CH₄ hydrate was formed by melting the fine ice powder at the temperature of 273.2 K under high pressure of ¹³CH₄. We retrieved the hydrate sample at 77 K and its Raman spectra was obtained at 123 K in the range 2,500-3,300 cm^-1 using a Raman spectrometer (RMP-210, JASCO Corporation). The Raman peaks were fitted in the range 2,800-3,000 cm^-1 for the C-H stretching peaks of methane using a Voigt function to obtain the integrated intensities of the two peaks corresponding to methane encaged in the large and small cages of the cubic structure I.

Raman shifts for the C-H stretching and bending modes of ¹³CH₄ was 0.8 cm^-1 and 14 cm^-1 smaller than those of ¹²CH₄, respectively, suggesting that ¹³C-H bonds affect its vibrational frequency. Hydration number of ¹³CH₄ was estimated as 6.00±0.02, almost the same as that of ¹²CH₄ (6.02±0.02). Therefore, Cage occupancies of ¹³CH₄ and ¹²CH₄ hydrates showed no difference between them.



Reference

Ozeki T, Kikuchi Y, Takeya S, Hachikubo A (2018) Phase equilibrium of isotopologue methane hydrates enclathrated CH₃D and CD₄. J Chem Eng Data 63(6): 2266-2270, doi: 0.1021/acs.jced.8b00203