Carbon dioxide adsorption to UiO-66: theoretical analysis of binding energy and NMR properties

Abstract

UiO-66 is one of the most valuable metal–organic frameworks because of its excellent adsorption capability for gas molecules and its high stability towards water. Herein we investigated adsorption of carbon dioxide (CO₂), acetone, and methanol to infinite UiO-66 using DFT calculations on an infinite system under periodic-boundary conditions and post-Hartree–Fock (SCS-MP2 and MP2.5) calculations on cluster models. Three to four molecules are adsorbed at each of four μ-OH groups bridging three Zr atoms in one unit cell (named Site I). Six molecules are adsorbed around three pillar ligands, where the molecule is loosely surrounded by three terephthalate ligands (named Site II). Also, six molecules are adsorbed around the pillar ligand in a different manner from that at Site II, where the molecule is surrounded by three terephthalate ligands (named Site III). Totally fifteen to sixteen CO₂ molecules are adsorbed into one unit cell of UiO-66. The binding energy (BE) decreases in the order Site I > Site III > Site II for all three molecules studied here and in the order acetone > methanol ≫ CO₂ in the three adsorption sites. At the site I, the protonic H atom of the μ-OH group interacts strongly with the negatively charged O atom of CO₂, acetone and methanol, which is the origin of the largest BE value at this site. Although the DFT calculations present these decreasing orders of BE values correctly, the correction by post-Hartree–Fock calculations is not negligibly small and must be added for obtaining better BE values. We explored NMR spectra of UiO-66 with adsorbed CO₂ molecules and found that the isotropic shielding constants of the ¹H atom significantly differ among no CO₂, one CO₂ (at Sites I, II, or III), and fifteen CO₂ adsorption cases (Sites I to III) but the isotropic ¹⁷O and ¹³C shielding constants change moderately by adsorption of fifteen CO₂ molecules. Thus, ¹H NMR measurement is a useful experiment for investigating CO₂ adsorption.