The adsorption and decomposition of acetic acid has been studied on Pd(110) using temperature-programmed desorption (TPD). On the clean surface, the acid dissociates to form a stable acetate, and hydrogen is desorbed at 300 K. Some of the acetate then decomposes at around 353 K to yield CO2 and H2 into the gas phase and leaves adsorbed carbon. The latter stabilises some of the acetates and results in the desorption temperatures being increased by as much as 100 K. Oxygen pre-dosing leads to changed characteristics including stabilisation of the acetate in a manner which produces an autocatalytic acetate decomposition, a ‘surface explosion’. In this way, mixed surface layers can be obtained showing characteristics of the clean surface acetate, the carbon-contaminated acetate and the oxygen-induced explosion. A model based on atomic adsorbate-induced ordering of the acetate layer is used to describe the autocatalytic decomposition.
[1]
M. Bwoker.
On the mechanism of ethanol synthesis on rhodium
,
1992
.
[2]
M. Barteau,et al.
Reactions of carboxylic acids on the Pd(111)-(2 × 2)O surface: multiple roles of surface oxygen atoms
,
1991
.
[3]
M. Bowker,et al.
Acetate formation and explosive decomposition during ethanol oxidation on Rh
,
1991
.
[4]
U. Memmert,et al.
Interaction of oxygen with a Pd(110) surface. I: Structures and coverages
,
1989
.
[5]
M. Bowker,et al.
XPS, UPS and thermal desorption studies of the adsorption and reactions of CH3CHO and CH3COOH with the Cu(110) surface
,
1981
.
[6]
J. Falconer,et al.
The kinetics and mechanism of the autocatalytic decomposition of HCOOH on clean Ni(110)
,
1974
.