Abstract
The interaction of CO with an attapulgite-supported Cu(ii)Cl2 catalyst has been examined in a micro-reactor arrangement. CO exposure to the dried, as-received catalyst at elevated temperatures leads to the formation of CO2 as the only identifiable product. However, phosgene production can be induced by using a catalyst pre-treatment where the supported Cu(ii)Cl2 sample is exposed to a diluted stream of chlorine. Subsequent CO exposure at ∼370 °C then leads to phosgene production. In order to investigate the origins of this atypical set of reaction characteristics, a series of X-ray absorption experiments were performed that were supplemented by DFT calculations. XANES measurements establish that at the elevated temperatures connected with phosgene formation, the catalyst is comprised of Cu+ and a small amount of Cu2+. Moreover, the data show that unique to the chlorine pre-treated sample, CO exposure at elevated temperature results in a short-lived oxidation of the copper. On the basis of calculated CO adsorption energies, DFT calculations indicate that a mixed Cu+/Cu2+ catalyst is required to support CO chemisorption.
Highlights
There is a rapidly increasing demand for polyurethanes as lightweight, robust and transparent components in manufacturing
This study has examined the interaction of CO with an industrial grade Cu(II)Cl2 oxy-chlorination catalyst
CO exposure to the dried, as-received catalyst at elevated temperatures leads to the formation of CO2 as the only identi able product, establishing a role for a CO oxidation pathway
Summary
There is a rapidly increasing demand for polyurethanes as lightweight, robust and transparent components in manufacturing.
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