We have investigated the photoinduced decomposition of formaldehyde (CH2O) on a rutile TiO2(100)-(1×1) surface at 355 nrn using ternperature-prograrnrned desorption. Products, formate (HCOO), methyl radic...We have investigated the photoinduced decomposition of formaldehyde (CH2O) on a rutile TiO2(100)-(1×1) surface at 355 nrn using ternperature-prograrnrned desorption. Products, formate (HCOO), methyl radical (CH3.), ethylene (C2H4), and methanol (CH3OH) have been detected. The initial step in the decomposition of CH2O on the futile TiO2(100)-(1×1) surface is the formation of a dioxyrnethylene intermediate in which the carbonyl O atom of CH2O is bound to a Ti atom at the five-fold-coordinated Ti4+ (Tisc) site and its carbonyl C atom bound to a nearby bridge-bonded oxygen (Oh) atom, respectively. During 355 nrn irradiation, the dioxymethylene intermediate can transfer an H atom to the Ob atom, thus forming HCOO directly, which is considered as the main reaction channel. In addition, the dioxyrnethylene intermediate can also transfer methylene to the Ob row and break the C-O bond, thus leaving the original carbonyl O atom at the Tisc site. After the transfer of methylene, several pathways to products are available. Thus, we have found that Ob atoms are intimately involved in the photoinduced decomposition of CH2O on the futile TiO2 (100)-(1× 1) surface.展开更多
基金supported by the National Natural Science Foundation of China(No.21673235 and No.21403224)the Youth Innovation Promotion Association CAS,and the Key Research Program of the Chinese Academy of Sciences
文摘We have investigated the photoinduced decomposition of formaldehyde (CH2O) on a rutile TiO2(100)-(1×1) surface at 355 nrn using ternperature-prograrnrned desorption. Products, formate (HCOO), methyl radical (CH3.), ethylene (C2H4), and methanol (CH3OH) have been detected. The initial step in the decomposition of CH2O on the futile TiO2(100)-(1×1) surface is the formation of a dioxyrnethylene intermediate in which the carbonyl O atom of CH2O is bound to a Ti atom at the five-fold-coordinated Ti4+ (Tisc) site and its carbonyl C atom bound to a nearby bridge-bonded oxygen (Oh) atom, respectively. During 355 nrn irradiation, the dioxymethylene intermediate can transfer an H atom to the Ob atom, thus forming HCOO directly, which is considered as the main reaction channel. In addition, the dioxyrnethylene intermediate can also transfer methylene to the Ob row and break the C-O bond, thus leaving the original carbonyl O atom at the Tisc site. After the transfer of methylene, several pathways to products are available. Thus, we have found that Ob atoms are intimately involved in the photoinduced decomposition of CH2O on the futile TiO2 (100)-(1× 1) surface.
