The major contribution of this stud

The major contribution of this study is the mapping of product
evolution profiles as a function of selected variables during CO2
photoreduction at a UV–vis irradiated Cu/Cu2O electrode. A selfconsistent
reaction scheme is proposed to account for the distribution
of the products CH3OH, C2H5OH, CH2O, C2H4O, and CH3COCH3.
Irradiation of the system with UV–vis light enabled efficient CO2
reduction at a very low potential (+0.20 V); the process removed
80% CO2 after two hours of photoelectrolysis.
CO2 conversion to products like CH3OH, C2H5OH, CH2O, C2H4O,
and CH3COCH3 depended on the formation of radicals such as OH
,
H
, and CH3
during the process. These radicals originated from electron/hole
formation upon irradiation of the Cu/Cu2O electrode with
UV–vis light. The biased potential of the electrode and the pH of
the solution drastically interfered in stabilization of the product
with the lowest oxidation state. Indeed, it was possible to favor
CH3OH generation by conducting photoelectrolysis during shorter
periods, in the following conditions: NaHCO3/Na2CO3 buffer solution,
pH 8, applied potential of +0.20 V, and irradiation with UV–
vis light.
Taken together, our results suggested that the photoelectrochemical
process conditions determine which products will
emerge at the end of the reaction. Further studies are in progress
to investigate other electrode materials and experimental conditions,
which shall enable the design of an effective and economical
method to convert CO2 into added-value products. Because the
process is complex, additional investigations will also be necessary
to improve reaction selectivity for potential future applications.
A