Issue 30, 2020, Issue in Progress

Enhanced methane gas storage in the form of hydrates: role of the confined water molecules in silica powders

Abstract

Methane hydrates are promising materials for storage and transportation of natural gas; however, the slow kinetics and inefficient water to hydrate conversions impede its broad scale utilisation. The purpose of the present study is to demonstrate rapid (2–3 h) and efficient methane hydrate conversions by utilising the water molecules confined in the intra- and inter-granular space of silica powders. All the experiments were conducted with amorphous silica (10 g) powders of 2–30 μm; 10–20 nm grain size, to mimic the hydrate formations in fine sand and clay dominated environments under moderate methane pressure (7–8 MPa). Encasing of methane molecules in hydrate cages was confirmed by Raman spectroscopic (ex situ) and thermodynamic phase boundary measurements. The present studies reveal that the water to hydrate conversion is relatively slower in 10–20 nm grain size silica, although the nucleation event is rapid in both silicas. The process of hydrate conversion is vastly diffusion-controlled, and this was distinctly observed during the hydrate growth in nanosize silica.

Graphical abstract: Enhanced methane gas storage in the form of hydrates: role of the confined water molecules in silica powders

Supplementary files

Article information

Article type
Paper
Submitted
24 Feb 2020
Accepted
29 Apr 2020
First published
07 May 2020
This article is Open Access
Creative Commons BY-NC license

RSC Adv., 2020,10, 17795-17804

Enhanced methane gas storage in the form of hydrates: role of the confined water molecules in silica powders

P. S. R. Prasad, B. S. Kiran and K. Sowjanya, RSC Adv., 2020, 10, 17795 DOI: 10.1039/D0RA01754J

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