Tuning the Selectivity between C2H2and CO2in Molecular Porous Materials

Katherine A. Forrest; Tony Pham; Kai Jie Chen; Xue Jiang; David G. Madden; Douglas M. Franz; Adam Hogan; Michael J. Zaworotko; Brian Space

doi:10.1021/acs.langmuir.1c02009

Tuning the Selectivity between C₂H₂and CO₂in Molecular Porous Materials

Katherine A. Forrest
, Tony Pham
, Kai Jie Chen
, Xue Jiang
, David G. Madden
, Douglas M. Franz
, Adam Hogan
, Michael J. Zaworotko
, Brian Space

Research output: Contribution to journal › Article › peer-review

Abstract

A combined experimental and theoretical study of C2H2 and CO2 adsorption and separation was performed in two isostructural molecular porous materials (MPMs): MPM-1-Cl ([Cu2(adenine)4Cl2]Cl2) and MPM-1-TIFSIX ([Cu2(adenine)4(TiF6)2]). It was revealed that MPM-1-Cl displayed higher low-pressure uptake, isosteric heat of adsorption (Qst), and selectivity for C2H2 than CO2, whereas the opposite was observed for MPM-1-TIFSIX. While MPM-1-Cl contains only one type of accessible channel, which has a greater preference toward C2H2, MPM-1-TIFSIX contains three distinct accessible channels, one of which is a confined region between two large channels that represents the primary binding site for both adsorbates. According to molecular simulations, the initial adsorption site in MPM-1-TIFSIX interacts more strongly with CO2 than C2H2, thus explaining the inversion of adsorbate selectivity relative to MPM-1-Cl.

Original language	English
Pages (from-to)	13838-13845
Number of pages	8
Journal	Langmuir
Volume	37
Issue number	47
DOIs	https://doi.org/10.1021/acs.langmuir.1c02009
Publication status	Published - 30 Nov 2021

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title = "Tuning the Selectivity between C2H2and CO2in Molecular Porous Materials",

abstract = "A combined experimental and theoretical study of C2H2 and CO2 adsorption and separation was performed in two isostructural molecular porous materials (MPMs): MPM-1-Cl ([Cu2(adenine)4Cl2]Cl2) and MPM-1-TIFSIX ([Cu2(adenine)4(TiF6)2]). It was revealed that MPM-1-Cl displayed higher low-pressure uptake, isosteric heat of adsorption (Qst), and selectivity for C2H2 than CO2, whereas the opposite was observed for MPM-1-TIFSIX. While MPM-1-Cl contains only one type of accessible channel, which has a greater preference toward C2H2, MPM-1-TIFSIX contains three distinct accessible channels, one of which is a confined region between two large channels that represents the primary binding site for both adsorbates. According to molecular simulations, the initial adsorption site in MPM-1-TIFSIX interacts more strongly with CO2 than C2H2, thus explaining the inversion of adsorbate selectivity relative to MPM-1-Cl.",

author = "Forrest, \{Katherine A.\} and Tony Pham and Chen, \{Kai Jie\} and Xue Jiang and Madden, \{David G.\} and Franz, \{Douglas M.\} and Adam Hogan and Zaworotko, \{Michael J.\} and Brian Space",

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doi = "10.1021/acs.langmuir.1c02009",

language = "English",

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AU - Forrest, Katherine A.

AU - Pham, Tony

AU - Chen, Kai Jie

AU - Jiang, Xue

AU - Madden, David G.

AU - Franz, Douglas M.

AU - Hogan, Adam

AU - Zaworotko, Michael J.

AU - Space, Brian

PY - 2021/11/30

Y1 - 2021/11/30

N2 - A combined experimental and theoretical study of C2H2 and CO2 adsorption and separation was performed in two isostructural molecular porous materials (MPMs): MPM-1-Cl ([Cu2(adenine)4Cl2]Cl2) and MPM-1-TIFSIX ([Cu2(adenine)4(TiF6)2]). It was revealed that MPM-1-Cl displayed higher low-pressure uptake, isosteric heat of adsorption (Qst), and selectivity for C2H2 than CO2, whereas the opposite was observed for MPM-1-TIFSIX. While MPM-1-Cl contains only one type of accessible channel, which has a greater preference toward C2H2, MPM-1-TIFSIX contains three distinct accessible channels, one of which is a confined region between two large channels that represents the primary binding site for both adsorbates. According to molecular simulations, the initial adsorption site in MPM-1-TIFSIX interacts more strongly with CO2 than C2H2, thus explaining the inversion of adsorbate selectivity relative to MPM-1-Cl.

AB - A combined experimental and theoretical study of C2H2 and CO2 adsorption and separation was performed in two isostructural molecular porous materials (MPMs): MPM-1-Cl ([Cu2(adenine)4Cl2]Cl2) and MPM-1-TIFSIX ([Cu2(adenine)4(TiF6)2]). It was revealed that MPM-1-Cl displayed higher low-pressure uptake, isosteric heat of adsorption (Qst), and selectivity for C2H2 than CO2, whereas the opposite was observed for MPM-1-TIFSIX. While MPM-1-Cl contains only one type of accessible channel, which has a greater preference toward C2H2, MPM-1-TIFSIX contains three distinct accessible channels, one of which is a confined region between two large channels that represents the primary binding site for both adsorbates. According to molecular simulations, the initial adsorption site in MPM-1-TIFSIX interacts more strongly with CO2 than C2H2, thus explaining the inversion of adsorbate selectivity relative to MPM-1-Cl.

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DO - 10.1021/acs.langmuir.1c02009

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AN - SCOPUS:85120034010

SN - 0743-7463

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SP - 13838

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JO - Langmuir

JF - Langmuir

IS - 47

ER -

Tuning the Selectivity between C₂H₂and CO₂in Molecular Porous Materials

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