Hydroquinone clathrates as hydrogen storage media: An analysis using Grand-Canonical Monte Carlo molecular simulation

IF 5.3 2区化学 Q2 CHEMISTRY, PHYSICAL

Journal of Molecular Liquids Pub Date : 2025-03-12 DOI:10.1016/j.molliq.2025.127366

Brais Rodríguez-García , Germán Pérez-Sánchez , Martín Pérez-Rodríguez , Manuel M. Piñeiro

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Abstract

Hydrates and clathrates have been suggested as potential gas separation and storage materials. For the case of hydrogen, previous results have evidenced that hydroquinone clathrates represent a feasible alternative for storage if compared to other options. The possibility of multiple clathrate cell occupation has been already demonstrated, so the key for a practical implementation of this solution is a detailed knowledge about the clathrate filling mechanism, and the upper occupancy limits. Identifying the optimal conditions required to enhance structure occupation, and the atomic scale nature of the inclusion process itself, leads to the possibility of increasing hydrogen volumetric storage capacity. In this study, the hydroquinone clathrate hydrogen filling process has been analyzed through atomistic Grand-Canonical Monte Carlo (GCMC) molecular simulations over a wide temperature and pressure range. The results obtained describe quantitatively the theoretical clathrate filling process, as well as the succession of multiple occupancy modes for the crystalline clathrate cells. The isotherms obtained have been correlated accurately using a mathematical model derived from the classical equation of Langmuir isotherms. The molecular simulation results presented describe the maximum hydrogen structural capacity, providing a valuable insight on the occurrence of multiple occupancy modes, a phenomenon not well described yet. The methodology used in this case can be extended to analyze hydrogen storage capacity inside other nanoporous materials.

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来源期刊

Journal of Molecular Liquids 化学-物理：原子、分子和化学物理

CiteScore

10.30

自引率

16.70%

发文量

2597

审稿时长

78 days

期刊介绍： The journal includes papers in the following areas: – Simple organic liquids and mixtures – Ionic liquids – Surfactant solutions (including micelles and vesicles) and liquid interfaces – Colloidal solutions and nanoparticles – Thermotropic and lyotropic liquid crystals – Ferrofluids – Water, aqueous solutions and other hydrogen-bonded liquids – Lubricants, polymer solutions and melts – Molten metals and salts – Phase transitions and critical phenomena in liquids and confined fluids – Self assembly in complex liquids.– Biomolecules in solution The emphasis is on the molecular (or microscopic) understanding of particular liquids or liquid systems, especially concerning structure, dynamics and intermolecular forces. The experimental techniques used may include: – Conventional spectroscopy (mid-IR and far-IR, Raman, NMR, etc.) – Non-linear optics and time resolved spectroscopy (psec, fsec, asec, ISRS, etc.) – Light scattering (Rayleigh, Brillouin, PCS, etc.) – Dielectric relaxation – X-ray and neutron scattering and diffraction. Experimental studies, computer simulations (MD or MC) and analytical theory will be considered for publication; papers just reporting experimental results that do not contribute to the understanding of the fundamentals of molecular and ionic liquids will not be accepted. Only papers of a non-routine nature and advancing the field will be considered for publication.