Issue 18, 2017, Issue in Progress

Mathematical modeling of gas desorption from a metal–organic supercontainer cavity filled with stored N2 gas at critical limits

Abstract

Metal–organic supercontainer (MOSC) molecules are ideal candidates for gas storage applications due to their construction with customizable ligands and tunable cavity and window sizes, which are found to be elastic in nature. Force field molecular dynamics (MD) are used to evaluate the utilization of MOSCs as nanoporous structures for gas storage. A MOSC, with nitrogen gas molecules filling the cavity, progresses through MD and releases gas molecules by applying temperature to the MOSC. It is the MOSC's elasticity which is responsible for the desorption of guests at elevated temperatures. Data obtained from MD serves as a guide for the derivation of analytical equations that can be used to describe and explain the mechanism of gas desorption from within the cavity. Mathematical modeling of gas desorption from the center cavity can provide a method of predicting MOSC behavior for a broader range of pressures and temperatures, which is challenging for direct atomistic modeling. The utilization of MD can provide data for a wide variety of properties and processes in various materials under different conditions for a broad range of technology-related applications.

Graphical abstract: Mathematical modeling of gas desorption from a metal–organic supercontainer cavity filled with stored N2 gas at critical limits

Supplementary files

Article information

Article type
Paper
Submitted
31 Aug 2016
Accepted
06 Feb 2017
First published
13 Feb 2017
This article is Open Access
Creative Commons BY-NC license

RSC Adv., 2017,7, 11180-11190

Mathematical modeling of gas desorption from a metal–organic supercontainer cavity filled with stored N2 gas at critical limits

W. Sapp, B. Gifford, Z. Wang and D. S. Kilin, RSC Adv., 2017, 7, 11180 DOI: 10.1039/C6RA21876H

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