The adsorption of oxygen on Ag(110): a new view of structure and bonding

Molecular dynamics simulation of O2 adsorption on Ag(110) from first principles electronic structure calculations

State of the art simulations show that the physisorption state could be important for O₂/Ag(110) adsorption.

Chemisorption and dissociation of single oxygen molecules on Ag(110)

The chemisorption of single oxygen molecules on Ag110 and the dissociation of the adsorbed molecules induced by tunneling electrons were studied at 13 K using a variable-low-temperature scanning tunneling microscope. Two predominant types of chemisorbed O2 molecules were identified, one with the O2 molecular axis aligned along the [001] direction of the substrate [O2(001)], and the other with the molecular axis aligned along the [110] direction [O2(110)]. Tunneling of electrons between the scanning tunneling microscope tip and O2(001) caused the molecule either to rotate or dissociate, depending on the direction of electron tunneling. In contrast, electron tunneling caused O2(110) to dissociate regardless of tunneling direction. In addition to O2(001) and O2(110), several other oxygen species and their dynamical behaviors were observed.

Orbital specific chemistry: Controlling the pathway in single-molecule dissociation

A scanning tunneling microscope (STM) was used to control the pathway of the dissociation of single O(2) molecules chemisorbed on Ag(110) at 13 K. Tunneling of electrons from the STM tip into the O(2) caused dissociation of the molecule, giving rise to two adsorbed O atoms separated along the [110] direction. In contrast, the ejection of electrons from the O(2) molecule produced adsorbed O atoms separated along the [001] direction. These results illustrate that control of the dissociation pathway and product formation are associated with a specific molecular orbital located at the Fermi level.