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Abstract
That polar and non-polar compounds do not spontaneously mix is a textbook rule of chemistry with few exceptions. Here we provide evidence for the intercalation of methane, ethane, and small hydrocarbons into the lattice structure of hydrogen cyanide (HCN), a highly polar molecule. Using cryogenic syntheses and Raman spectroscopy, we observe distinct shifts in vibrational modes in line with enhanced hydrogen bonding upon hydrocarbon insertion. Co-crystal structures composed of HCN and ethane that are both thermodynamically stable, and that closely match measured vibrational shifts are computationally predicted. Methane, ethane and HCN are major components of the atmosphere and surface of Saturn’s moon Titan, where they play key roles in shaping chemistry, weather, and landscape. Their intermixing may prove instrumental for explaining Titan’s chemical and geological evolution.
Supplementary materials
Title
SUPPORTING INFORMATION
Description
Materials and Methods
Supplementary Text
Figs S1-S17
Tables S1-S7
References (S1-S13)
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Title
Selection of optimised crystal structures
Description
The HCN ground state, the two phases discussed in the main text, alongside two additional structures shown in the supporting information.
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