Detection and quantification of steady-state ethylene oxide formation over an Ag(1 1 1) single crystal

Extensive experiments with a flow reactor were performed to reliably detect the steady-state catalytic formation of ethylene oxide from ethylene and oxygen on an Ag(1 1 1) single crystal. For single crystals with their small surfaces, this had been a major experimental problem because of the low reaction probability of ethylene and cross-sensitivities in the mass spectra. Using 16O2 ethylene oxide could be detected on mass fragment m/z = 43, using 18O2 on m/z = 31 and m/z = 45, but strong time-dependent background signals had to be subtracted. This was achieved by periodic temperature changes of the reactor. After proper inclusion of all effects, a mole fraction of ethylene oxide of only 3 × 10−5 with respect to the reaction gas mixture, which was unequivocally produced by catalysis on the Ag sample, could be determined with a signal-to-noise ratio of more than one order of magnitude above the detection limit.

Detection of steady-state ethylene oxide formation on Ag single crystals is a major experimental problem because of the low reaction probability of ethylene and cross-sensitivities in the mass spectra. It is shown that with carefully chosen parameters and by periodic operation even trace amounts of ethylene oxide can be detected in a flow reactor.Figure optionsDownload high-quality image (167 K)Download as PowerPoint slideHighlights
► Ethylene oxide was formed by catalytic reaction on an Ag(1 1 1) single crystal.
► Cross-sensitivities with other compounds in the mass spectra were essential.
► By periodic operation of the reactor, a background signal was subtracted.
► Even trace amounts of ethylene oxide could be quantitatively determined.