Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite

Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite

Adsorption of fluids in nanoporous materials is important for several applications including gas storage and catalysis. The pore network in natural, as well as engineered, materials can exhibit different degrees of connectivity between pores. While this might have important implications for the sorp...

Full description

Bibliographic Details
Main Authors: Siddharth Gautam, David R. Cole
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:ChemEngineering
Subjects:
pore connectivity
CO<sub>2</sub>
ethane
adsorption
silicalite
GCMC simulation
Online Access:https://www.mdpi.com/2305-7084/5/3/55
id doaj-1c65edb1b9ec458894e2bed877c175d7
record_format Article
spelling doaj-1c65edb1b9ec458894e2bed877c175d72021-09-25T23:53:52ZengMDPI AGChemEngineering2305-70842021-08-015555510.3390/chemengineering5030055Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in SilicaliteSiddharth Gautam0David R. Cole1School of Earth Sciences, The Ohio State University, 275 Mendenhall Laboratory, 125 S Oval Mall, Columbus, OH 43210, USASchool of Earth Sciences, The Ohio State University, 275 Mendenhall Laboratory, 125 S Oval Mall, Columbus, OH 43210, USAAdsorption of fluids in nanoporous materials is important for several applications including gas storage and catalysis. The pore network in natural, as well as engineered, materials can exhibit different degrees of connectivity between pores. While this might have important implications for the sorption of fluids, the effects of pore connectivity are seldom addressed in the studies of fluid sorption. We have carried out Monte Carlo simulations of the sorption of ethane and CO<sub>2</sub> in silicalite, a nanoporous material characterized by sub-nanometer pores of different geometries (straight and zigzag channel like pores), with varied degrees of pore connectivity. The variation in pore connectivity is achieved by selectively blocking some pores by loading them with methane molecules that are treated as a part of the rigid nanoporous matrix in the simulations. Normalized to the pore space available for adsorption, the magnitude of sorption increases with a decrease in pore connectivity. The increased adsorption in the systems where pore connections are removed by blocking them is because of additional, albeit weaker, adsorption sites provided by the blocker molecules. By selectively blocking all straight or zigzag channels, we find differences in the absorption behavior of guest molecules in these channels.https://www.mdpi.com/2305-7084/5/3/55pore connectivityCO<sub>2</sub>ethaneadsorptionsilicaliteGCMC simulation
collection DOAJ
language English
format Article
sources DOAJ
author Siddharth Gautam
David R. Cole
spellingShingle Siddharth Gautam
David R. Cole
Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite
ChemEngineering
pore connectivity
CO<sub>2</sub>
ethane
adsorption
silicalite
GCMC simulation
author_facet Siddharth Gautam
David R. Cole
author_sort Siddharth Gautam
title Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite
title_short Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite
title_full Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite
title_fullStr Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite
title_full_unstemmed Effects of Pore Connectivity on the Sorption of Fluids in Nanoporous Material: Ethane and CO<sub>2</sub> Sorption in Silicalite
title_sort effects of pore connectivity on the sorption of fluids in nanoporous material: ethane and co<sub>2</sub> sorption in silicalite
publisher MDPI AG
series ChemEngineering
issn 2305-7084
publishDate 2021-08-01
description Adsorption of fluids in nanoporous materials is important for several applications including gas storage and catalysis. The pore network in natural, as well as engineered, materials can exhibit different degrees of connectivity between pores. While this might have important implications for the sorption of fluids, the effects of pore connectivity are seldom addressed in the studies of fluid sorption. We have carried out Monte Carlo simulations of the sorption of ethane and CO<sub>2</sub> in silicalite, a nanoporous material characterized by sub-nanometer pores of different geometries (straight and zigzag channel like pores), with varied degrees of pore connectivity. The variation in pore connectivity is achieved by selectively blocking some pores by loading them with methane molecules that are treated as a part of the rigid nanoporous matrix in the simulations. Normalized to the pore space available for adsorption, the magnitude of sorption increases with a decrease in pore connectivity. The increased adsorption in the systems where pore connections are removed by blocking them is because of additional, albeit weaker, adsorption sites provided by the blocker molecules. By selectively blocking all straight or zigzag channels, we find differences in the absorption behavior of guest molecules in these channels.
topic pore connectivity
CO<sub>2</sub>
ethane
adsorption
silicalite
GCMC simulation
url https://www.mdpi.com/2305-7084/5/3/55
work_keys_str_mv AT siddharthgautam effectsofporeconnectivityonthesorptionoffluidsinnanoporousmaterialethaneandcosub2subsorptioninsilicalite
AT davidrcole effectsofporeconnectivityonthesorptionoffluidsinnanoporousmaterialethaneandcosub2subsorptioninsilicalite
_version_ 1717367638433202176

Similar Items