Figure 2.13 Structures of CN before (a) and after (b) doping with carbon chains. (c) Electrochemical impedance spectroscopy (EIS) Nyquist plots under irradiation condition. Inset: Periodic on/off photocurrent response under visible‐light irradiation. (d) Comparison of the photocatalytic CO2 reduction rate of the samples with different amount of glycine, respectively.
Source: Ren et al. [70].
On the other hand, it is reported that CO can originate from the secondary photolysis of unstable reduced products, such as HCO2H. For example, Frei and coworker investigated the reaction mechanism of CO2 photoreduction over Ti silicalite molecular sieve in the presence of methanol as electron donor by means of in situ FTIR [73]. It was found that HCO2H, CO, and HCO2CH3 as reduced products were detected, in which mass proportion of CO was the highest. The formation of the products was studied through the infrared analysis of experiments with isotope‐labeled reactants, such as C18O2, 13CO2, and 13CH3OH. The results inferred that the produced CO is derived from secondary photolysis of the reduced HCO2H. In contrast, the formic acid is the primary two‐electron reduction product of CO2 at the ligand‐to‐metal charge transfer transition (LMCT) excited Ti centers. This means that since the complex hydrocarbons are the target products, the photolysis effect should be paid more attention for suppressing the formation of CO.
2.4.3 Dioxygen (O2)
As discussed above, an ideal artificial photosynthesis system usually contains at least three different components: light harvesting, water oxidation, and CO2 reduction [74]. To achieve CO2 photoreduction accompanied with water oxidation, early single integrated systems are composed of semiconducting metal oxide with large band gaps absorbing UV light and metal or metal oxide cocatalysts, where considerable efforts are paid to functionalizing these materials and exploring various modifications [75]. Nevertheless, since the assembly of multifunctional units in an integrated device is extremely difficult, an alternative strategy is to divide the overall process into two half‐reactions: water oxidation and CO2 reduction. Once each half‐reaction is well understood and optimized, the two reactions can be coupled in an integrated device. For example, it is demonstrated that combining two semiconductor materials in tandem (Z‐scheme) mode can efficiently extend the light response into the visible region [76]. Recently, Arai et al. reported a photoelectrochemical system consisting of SrTiO3 photoanode for water oxidation and InP photocathode for CO2 reduction that produced O2 and formate, respectively [77]. Besides, mononuclear [Ru(bpy)3]2+ is often combined with S2O82− sacrificial acceptor to evaluate water oxidation photocatalysis systems in aqueous photosensitization system in the past decades [78]. For example, upon combining mild oxidant [Ru(bpy)]33+ of well‐defined potential (+1.26 V) with a Co3O4 nanotube in neutral aqueous solution, a hole can be efficiently transferred to the catalyst [79]. Subsequently, four holes transfer from [Ru(bpy)3]3+ to Co3O4 and react with two H2O molecules to O2 and 4H+, which indicates that Co3O4 is appropriate candidate for use in an artificial photosynthetic assembly.
On the water oxidation side, several groups proposed approaches to overcome challenges of efficiently combining molecular light absorbers with multi‐electron water oxidation catalyst inspired by the tyrosine mediator design of nature's photosystem II. For instance, the Mallouk group reported a series of researches on coupling of Ir oxide nanocluster (IrOx) with [Ru(bpy)3]2+ or a porphyrin visible‐light absorber through a benzimidazole–phenol redox linking with both components covalently anchored on a TiO2 surface [80]. Based on the results of transient optical spectroscopy, when the Ru chromophore absorbs a visible photon, an photoinduced electron injects into TiO2 at an ultrafast speed, and subsequently an electron transfers from the benzimidazole–phenol mediator to the oxidized Ru complex for reducing the oxidized chromophore