Surface Aspects of Semiconductor Photochemistry

The Surfaces Special Issue entitled “Surface Aspects of Semiconductor Photochemistry” is mainly devoted to the 7th International Conference on Semiconductor Photochemistry (SP7), which was held on 11–14 September 2019 in Milano, Italy, in the beautiful Renaissance “ Ca’ Granda ” main building of the University Milan. The conference saw the active participation of more than 160 attendants in an intense program, including 12 plenary and keynote lectures, 60 oral presentations, 20 ﬂash presentations by young authors and 2 poster sessions. This Special Issue, collecting 6 original contributions and one literature review, well highlights the main aim of the SP7 conference to cover the current developments in the area of semiconductor photochemistry and photo(electro)catalysis, focusing speciﬁc attention on either new ﬁndings related to “historical” TiO 2 -based materials or to up-to-date results obtained with emerging and promising semiconductor photo(electro)catalytic materials.

processes involving light harvesting and semiconductor excitation, in relation to bulk diffusion, surface trapping and interfacial transfer of the electrons and holes photoproduced on the semiconductor surface upon irradiation [22,[31][32][33].
In this context, within this special issue Vorontsov et al. [34] provide an overview on recent findings concerning the peculiar role played by the surface chemistry of anatase TiO 2 on both photocatalytic and photo(electro)catalytic processes. Particular attention is focused on the use of the semiconductor crystal facets engineering as an important and powerful strategy to properly tune and optimize both the physico-chemical properties and the substrate-and reaction-sensitive activity of the photocatalysts [35][36][37]. Therefore, as no unambiguous conclusion has been yet drawn about either the photoactivity order of clean anatase crystal facets, or their optimal balance to maximize photoactivity, general understanding needs to be developed, together with prediction methods, to properly select shaped-controlled TiO 2 materials, able to selectively promote specific photocatalytic processes.
At the same time, either metal/cation [38] or non-metal/anion [39,40] doping has been largely pursued to extend the spectral breadth and efficiency of TiO 2 photoresponse. The still under debate nature and effectiveness of doping titanium dioxide with heteroatoms is testified by the huge and progressively increasing number of studies in the field. The charged carrier recombination and the interfacial electron transfer rates can be significantly altered by semiconductor doping. For instance, the photoreactivity of doped TiO 2 is influenced by several parameters such as the dopant concentration, the energy levels of dopants differently located within the TiO 2 lattice, their electronic configuration, as well as by the irradiation intensity. Therefore, the specific preparation method is expected to have significant impact on the overall photoactivity of doped TiO 2 .
Among the different methods employed to obtain doped TiO 2 films, in the special issue Arab et al. [41] report a systematic investigation on the optical and photoelectrochemical properties of Ni-doped TiO 2 layers obtained using the quite innovative plasma electrolytic oxidation (PEO) technique, carried out in galvanostatic mode in alkaline electrolytes containing nickel acetate as Ni source. Compared to traditional anodizing procedures leading to the formation of TiO 2 nanotube arrays, the PEO process works at higher current and higher voltage, but it requires a very short processing time (less than 10 min), allowing high rates of oxide growth (ca. 1 µm min −1 ). Furthermore, the high pressure and temperature locally induced by sparking can significantly affect the oxide morphology, crystal structure and composition, promoting instantaneous oxide crystallization and incorporation of chemical species from the electrolyte. This confirms the wide potential application of PEO at the industrial scale not only for the synthesis of protective coatings, but also for the preparation of large area electrodes for photo(electro)catalytic water treatment [42].
Concerning non-metal doped TiO 2 -based photocatalysts, Chen et al. [43] succeeded in preparing photoactive nitrogen-doped TiO 2 powders with controlled micro/macroporous multi-scale structure by adopting a microphase separation method. In particular, these authors systematically investigated the key role played by the addition of citric acid, instead of any other hard or soft templating agent, to obtain a stable macroporous framework, able to positively contribute to the photoactivity of the resultant TiO 2 , mainly due to enhanced light absorption efficiency.
Regarding industrial applications of photocatalysis, Bianchi et al. [44] report on the use of a digital printing process for the preparation of functionalized industrial porcelain-grès tiles, working as self-cleaning photocatalytic building materials. By the employed economic and fast procedure, a homogeneous distribution of micro-sized TiO 2 materials surface decorated with Ag nanoparticles can be obtained, with excellent photocatalytic antimicrobial activity on Gram-negative pathogenic bacteria such as E. coli, under both indoor and outdoor irradiation. A mechanism involving the efficient photocatalytic production of reactive oxygen species due to enhanced charge carrier separation in Ag-TiO 2 fixed powders is proposed to explain the good photocatalytic ability of such tiles with respect to standard systems containing only Ag + species.
In relation to heterogeneous photocatalysis investigations for the chemical synthesis of added-value organic compounds, the contribution of Vaiano et al. [45] deals with the preliminary study on the selective photocatalyzed cyclohexane oxydehydrogenation to benzene and cyclohexene products in the presence of MoO x -functionalized ferrierite zeolites in a gas-solid continuous flow reactor under UV irradiation. A possible mechanism initiated by the photoactivation of polymolybdate species for the selective conversion of cyclohexane is proposed, which sheds light on the peculiar role played by the interaction between the zeolite and the molybdenum oxide species in modifying the catalyst selectivity.
Focusing attention on new promising semiconductor photocatalysts able to maximize the exploitation of visible light to promote water oxidation, BiVO 4 , with its relatively narrow bandgap of 2.4 eV, emerged thanks to its visible light absorption properties, its stability over a wide pH range and valence band edge position suitable for water oxidation. In spite of these attractive features, BiVO 4 photoanodes suffer from low majority carrier mobility, limited charge separation and relatively poor water oxidation kinetics [46]. In this regard, Pedroni et al. [47] confirmed that the combination of BiVO 4 with WO 3 in a heterojunction system fabricated by means of reactive radio frequency plasma (co)sputtering may lead to improved charge separation. The so obtained coupled system, properly optimized in relation to both the WO 3 bilayer thickness and the adopted post calcination temperature, can efficiently exploit the visible-light photoactivity of BiVO 4 together with the intrinsic efficient charge transport properties of the WO 3 semiconductor, with an overall significant synergistic increase of the photoelectrochemical performance under solar light irradiation. By means of incident photon to current efficiency measurements, the authors support previously reported findings unveiling the wavelength-dependent charge carrier interactions occurring at the interface between the two oxides [48][49][50]. In particular, while under selective BiVO 4 excitation (at wavelength above 450 nm) the electrons photoexcited in BiVO 4 conduction band are efficiently injected into WO 3 , upon the excitation of both semiconductors (at wavelength below 450 nm) a detrimental recombination channel opens at the interface, between the electrons photo-promoted in the WO 3 conduction band and the holes photo-produced in the BiVO 4 valence band, which results in a decrease of the overall photoelectrochemical performance of the coupled system.
The Special Issue is completed by the contribution of Polo et al. [51], presenting a systematic study on the effects induced by post-synthesis hydrogenation on the photoelectrochemical performances of zinc ferrite (ZnFe 2 O 4 ) flat films photoanodes for water oxidation as a function of the pre-annealing temperature adopted in their synthesis. In fact, zinc ferrite has been recently explored as a binary oxide alternative to the much more investigated Fe 2 O 3 , especially thanks to its remarkable thermal and chemical stability together with a relatively narrow energy band gap of ca. 2.0 eV [52,53]. However, the performance of ZnFe 2 O 4 is mainly limited by an inefficient charge separation in the bulk with respect to the hole transport towards the film/electrolyte interface. In this regard, a reductive treatment under H 2 atmosphere was carried out under mild heating conditions with the main aim of improving the electron conductivity of the films through the introduction of oxygen vacancies acting as n-type dopants. Interestingly, the investigation was focused on flat zinc ferrite films with moderate thickness, i.e., ca. 100 nm thick, prepared according to a generalized approach for ternary metal oxides, which offers an easily processable green route to obtain optically transparent films suitable to be employed as photoanodes in dual absorber tandem photoelectrochemical cells [54]. In relation with previous findings [55], Polo et al. demonstrate how specific structural and/or surface properties, together with the initial film morphology, differently affect the overall contribution of post-synthesis hydrogenation to the efficiency of zinc ferrite-based photoanodes.
We are confident that this Special Issue will help the reader to get a concise but updated view concerning efforts and advances recently made toward a better understanding of the multiple surface aspects governing the continuously evolving field of semiconductor photochemistry.
Funding: This research received no external funding.
Acknowledgments: Guest Editors would like to thank all Authors and Reviewers of this Special Issue for their valuable contributions.

Conflicts of Interest:
The authors declare no conflict of interest.