Title

Insights into the Anomalous Vibrational Frequency Shifts of CO 2 Adsorbed to Metal Sites in Microporous Frameworks

Abstract

Diffuse reflectance infrared (IR) spectroscopy was used to study the structure and dynamics of H2 and CO2 adsorbed within the isostructural metalorganic frameworks M2L (M = Mg, Mn, Fe, Co, Zn; L = 2,5-dioxidobenzene-1,4-dicarboxylate) referred to as M-MOF-74 and CPO-27-M. Cluster models of the primary adsorption site were excised from periodic models that were optimized using plane-wave density functional theory at the PerdewBurkeErnzerhof (PBE) level. Models incorporating an adsorbed H2 or CO2 were optimized using dispersion-corrected density functional theory (DFT), and the anharmonic vibrational frequencies of the adsorbate were calculated using the discrete variable representation method. The calculated vibrational frequency shifts reveal the same trend among the M2L materials as those observed experimentally and provide insight into the origins of these shifts. Our experimental spectra of adsorbed CO2 confirm a unique blue shift of the v(3) mode for molecules adsorbed in Mg2L, while the frameworks assembled from transition metals induce a red shift. By shifting the focus to the CO2 local vibrational modes, a deeper insight into the influence of back bonding (metal d-electron density donation into CO2 pi* orbitals) is revealed; for Mg2L there is a near-complete cancellation of the opposing local mode contributions to the observed frequency shift. Additional spectral features in the CO2 v(3) region are assigned to (1) the v(3) mode of the (CO2)-C-13 isotopologue, (2) a combination mode involving a v(2) excitation, and (3) librational sidebands arising from center-of-mass motion of the adsorbed molecule on the surface. Interestingly, below 100 K we observe the appearance of a new band that is distinct from the primary v(3) band observed at room temperature. This band is attributed to an alternate, localized orientation of CO2 adsorbed to the metal site, which is supported by the DFT model.

Publisher

American Chemical Society

Publication Date

3-12-2015

Publication Title

Journal of Physical Chemistry C

Department

Chemistry and Biochemistry

Document Type

Article

DOI

10.1021/jp5104356

Notes

Record for J.L.C. Rowsell. Additional record for S. FitzGerald: https://digitalcommons.oberlin.edu/faculty_schol/3295/

Keywords

Initio molecular-dynamics, Total-energy calculations, Wave basis-set, Organic frameworks, Carbon-dioxide, Hydrogen adsorption, Neutron-scattering

Language

English

Format

text

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