Systematic Investigation of CO2 Adsorption Energetics in Metal-Organic Frameworks Based on Imidazolyl Linkers

Gerson J. Leonel; Tamilarasan Subramani; Alexandra Navrotsky

doi:10.1021/acs.jpcc.3c04909

Systematic Investigation of CO₂ Adsorption Energetics in Metal-Organic Frameworks Based on Imidazolyl Linkers

Gerson J. Leonel, Tamilarasan Subramani, Alexandra Navrotsky

Molecular Sciences, School of (SMS)

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

Abstract

This study explores system dependence (from the choice of metal and ligand) in the energetics for CO₂ confinement in 3-dimensional (3D) metal-organic frameworks (MOFs) employing imidazolyl ligands, namely, ditopic 2-methylimidazole (HMeIm) in Zn(MeIm)₂ (ZIF-8), Co(MeIm)₂ (ZIF-67), and tetratopic tetrakis(imidazolyl) boric acid (HB(MeIm)₄) in CuB(MeIm)₄ (Cu-BIF-3). All frameworks have a sodalite topology. Direct gas adsorption calorimetric experiments enable quantitation of energetic drive for CO₂ confinement in the frameworks. The general trend in the integral adsorption enthalpy ΔH_int (kJ/mol) is Cu-BIF-3 > ZIF-8 > ZIF-67. In ZIFs, greater porosity is consistent with more favorable CO₂ incorporation. Overall, the use of larger linkers in BIFs provides the greatest enhancement of the energetics of CO₂ adsorption in MOFs. The strength of guest-host interactions depends strongly on the choice of linker and metal.

Original language	English (US)
Pages (from-to)	19973-19978
Number of pages	6
Journal	Journal of Physical Chemistry C
Volume	127
Issue number	40
DOIs	https://doi.org/10.1021/acs.jpcc.3c04909
State	Published - Oct 12 2023

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
General Energy
Physical and Theoretical Chemistry
Surfaces, Coatings and Films

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title = "Systematic Investigation of CO2 Adsorption Energetics in Metal-Organic Frameworks Based on Imidazolyl Linkers",

abstract = "This study explores system dependence (from the choice of metal and ligand) in the energetics for CO2 confinement in 3-dimensional (3D) metal-organic frameworks (MOFs) employing imidazolyl ligands, namely, ditopic 2-methylimidazole (HMeIm) in Zn(MeIm)2 (ZIF-8), Co(MeIm)2 (ZIF-67), and tetratopic tetrakis(imidazolyl) boric acid (HB(MeIm)4) in CuB(MeIm)4 (Cu-BIF-3). All frameworks have a sodalite topology. Direct gas adsorption calorimetric experiments enable quantitation of energetic drive for CO2 confinement in the frameworks. The general trend in the integral adsorption enthalpy ΔHint (kJ/mol) is Cu-BIF-3 > ZIF-8 > ZIF-67. In ZIFs, greater porosity is consistent with more favorable CO2 incorporation. Overall, the use of larger linkers in BIFs provides the greatest enhancement of the energetics of CO2 adsorption in MOFs. The strength of guest-host interactions depends strongly on the choice of linker and metal.",

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N2 - This study explores system dependence (from the choice of metal and ligand) in the energetics for CO2 confinement in 3-dimensional (3D) metal-organic frameworks (MOFs) employing imidazolyl ligands, namely, ditopic 2-methylimidazole (HMeIm) in Zn(MeIm)2 (ZIF-8), Co(MeIm)2 (ZIF-67), and tetratopic tetrakis(imidazolyl) boric acid (HB(MeIm)4) in CuB(MeIm)4 (Cu-BIF-3). All frameworks have a sodalite topology. Direct gas adsorption calorimetric experiments enable quantitation of energetic drive for CO2 confinement in the frameworks. The general trend in the integral adsorption enthalpy ΔHint (kJ/mol) is Cu-BIF-3 > ZIF-8 > ZIF-67. In ZIFs, greater porosity is consistent with more favorable CO2 incorporation. Overall, the use of larger linkers in BIFs provides the greatest enhancement of the energetics of CO2 adsorption in MOFs. The strength of guest-host interactions depends strongly on the choice of linker and metal.

AB - This study explores system dependence (from the choice of metal and ligand) in the energetics for CO2 confinement in 3-dimensional (3D) metal-organic frameworks (MOFs) employing imidazolyl ligands, namely, ditopic 2-methylimidazole (HMeIm) in Zn(MeIm)2 (ZIF-8), Co(MeIm)2 (ZIF-67), and tetratopic tetrakis(imidazolyl) boric acid (HB(MeIm)4) in CuB(MeIm)4 (Cu-BIF-3). All frameworks have a sodalite topology. Direct gas adsorption calorimetric experiments enable quantitation of energetic drive for CO2 confinement in the frameworks. The general trend in the integral adsorption enthalpy ΔHint (kJ/mol) is Cu-BIF-3 > ZIF-8 > ZIF-67. In ZIFs, greater porosity is consistent with more favorable CO2 incorporation. Overall, the use of larger linkers in BIFs provides the greatest enhancement of the energetics of CO2 adsorption in MOFs. The strength of guest-host interactions depends strongly on the choice of linker and metal.

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Systematic Investigation of CO₂ Adsorption Energetics in Metal-Organic Frameworks Based on Imidazolyl Linkers

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