Greenhouse gas such as CO2 is the primary cause of global warming. Alternative energy source
should be provided without producing more CO2, such as solar energy. One of the best routes to remedy
CO2 is to transform it to hydrocarbons using photo reduction. In our study, CO2 was photocatalytically reduced to produce methanol using a Hg lamp with wavelength 365 nm in a steady-state optical-fiber photo
reactor. The optical-fiber photo reactor, comprised of near 120 Cu/TiO2-coated fibers, was designed and
assembled to transmit and spread light uniformly inside reactor. TiO2 film was coated on optical fiber using
dip-coating method. Titania and Cu-loaded solutions were prepared by a thermal hydrolysis method. The
thickness of Cu/TiO2 film was 53 nm and consisted of very fine spherical particle with diameter of near
14 nm. The XRD spectra indicated the anatase phase of all TiO2 and Cu/TiO2 films. The wavelength of
absorption edge was on 367 nm, equivalent to near 3.3 eV. Most active Cu species on TiO2 surface were Cu2O clusters, and played an important role for the formation of methanol. The methanol yield increased with
UV irradiative intensity. Photo activity increased with increasing Cu loadings. Maximum methanol rate was
0.45 μmole/g-cat•hr using 1.2 wt%-Cu/TiO2 catalyst under 16 W / cm2 irradiation, 1.3 bar pressure of CO2, and 5000 seconds mean residence time. Higher than 1.2 wt% Cu loading gave less rate of methanol yield
because of the masking effect of Cu2O clusters on the surface of TiO2.
