Adsorption of CO on the Fe3O4(001) Surface

TL;DR

This study investigates how carbon monoxide interacts with the Fe3O4(001) surface using various surface analysis techniques, revealing weak adsorption primarily at defects and a phase transition in CO coverage.

Contribution

It provides detailed insights into CO adsorption behavior on Fe3O4(001), including adsorption sites, coverage-dependent desorption, and the nature of the adsorbed species, which was not previously characterized in detail.

Findings

Weak CO adsorption mainly at surface defects

Coverage-dependent desorption temperature shifts

No surface reduction or carburization observed

Abstract

The interaction of CO with the Fe3O4(001)-(rt2xrt2)R45{\deg} surface was studied using temperature programmed desorption (TPD), scanning tunneling microscopy (STM) and x-ray photoelectron spectroscopy (XPS), the latter both under ultrahigh vacuum (UHV) conditions and in CO pressures up to 1 mbar. In general, the CO-Fe3O4 interaction is found to be weak. The strongest adsorption occurs at surface defects, leading to small TPD peaks at 115 K, 130 K and 190 K. Desorption from the regular surface occurs in two distinct regimes. For coverages up to 2 CO molecules per (rt2xrt2)R45{\deg} unit cell, the desorption maximum shows a large shift with increasing coverage, from initially 105 K to 70 K. For coverages between 2 and 4 molecules per (rt2xrt2)R45{\deg} unit cell, a much sharper desorption feature emerges at 50 K. Thermodynamic analysis of the TPD data suggests a phase transition from a dilute 2D gas into an ordered overlayer with CO molecules bound to surface Fe3+ sites. XPS data acquired at 45 K in UHV are consistent with physisorption. Some carbon-containing species are observed in the near-ambient-pressure XPS experiments at room temperature, but are attributed to contamination and/or reaction with CO with water from the residual gas. No evidence was found for surface reduction or carburization by CO molecules.