Reduction of Cofed Carbon Dioxide Modifies the Local Coordination Environment of Zeolite-Supported, Atomically Dispersed Chromium to Promote Ethane Dehydrogenation.
Wenqi ZhouNoah FelveyJiawei GuoAdam S HoffmanSimon R BareAmbarish R KulkarniRon C RunnebaumColeman X KronawitterPublished in: Journal of the American Chemical Society (2024)
The reduction of CO 2 is known to promote increased alkene yields from alkane dehydrogenations when the reactions are cocatalyzed. The mechanism of this promotion is not understood in the context of catalyst active-site environments because CO 2 is amphoteric, and even general aspects of the chemistry, including the significance of competing side reactions, differ significantly across catalysts. Atomically dispersed chromium cations stabilized in highly siliceous MFI zeolite are shown here to enable the study of the role of parallel CO 2 reduction during ethylene-selective ethane dehydrogenation. Based on infrared spectroscopy and X-ray absorption spectroscopy data interpreted through calculations using density functional theory (DFT), the synthesized catalyst contains atomically dispersed Cr cations stabilized by silanol nests in micropores. Reactor studies show that cofeeding CO 2 increases stable ethylene-selective ethane dehydrogenation rates over a wide range of partial pressures. Operando X-ray absorption near-edge structure (XANES) and extended X-ray absorption fine-structure (EXAFS) spectra indicate that during reaction at 650 °C the Cr cations maintain a nominal 2+ charge and a total Cr-O coordination number of approximately 2. However, CO 2 reduction induces a change, correlated with the CO 2 partial pressure, in the population of two distinct Cr-O scattering paths. This indicates that the promotional effect of parallel CO 2 reduction can be attributed to a subtle change in Cr-O bond lengths in the local coordination environment of the active site. These insights are made possible by simultaneously fitting multiple EXAFS spectra recorded in different reaction conditions; this novel procedure is expected to be generally applicable for interpreting operando catalysis EXAFS data.
Keyphrases
- density functional theory
- carbon dioxide
- ionic liquid
- high resolution
- molecular dynamics
- dual energy
- electronic health record
- room temperature
- computed tomography
- machine learning
- metal organic framework
- minimally invasive
- wastewater treatment
- molecular docking
- air pollution
- mass spectrometry
- anaerobic digestion
- solar cells