What question did this study set out to answer?

This research aims to investigate the structural and thermodynamic properties of xenon clathrate hydrate using advanced computational methods.

April 25, 2026Open Access

DFT investigation of xenon clathrate hydrates: Thermodynamic properties and structural insights

Key Points

This research aims to investigate the structural and thermodynamic properties of xenon clathrate hydrate using advanced computational methods.
Used density functional theory with PBE, vdW-DF2, and revPBE-D3(0) functionals.
Performed quasi-harmonic approximation calculations for thermal expansion and elastic properties.
Compared theoretical results with experimental data for validation.
The revPBE-D3(0) functional accurately predicts lattice parameters and bulk moduli.
Stability range predicted correctly up to 2.6 GPa.
QHA calculations yielded thermal expansion values consistent with available data.

Abstract

The structural, energetic, and thermodynamic properties of xenon (Xe) clathrate hydrate were investigated in this study using density functional theory with PBE, vdW-DF2, and revPBE-D3(0) exchange–correlation functionals. Among these functionals, the dispersion-corrected revPBE-D3(0) functional reproduces the experimental lattice parameters and bulk moduli with excellent accuracy. Moreover, this functional provides the best overall agreement with experiments, correctly predicting the stability range up to 2.6 GPa. Quasi-harmonic approximation (QHA) calculations yield thermal expansion and elastic properties consistent with available data. The combination of revPBE-D3(0) and QHA thus offers a robust framework for describing noble-gas hydrates.

DFT investigation of xenon clathrate hydrates: Thermodynamic properties and structural insights

Key Points

Abstract

Cite This Study