Sunlight-Operated TiO2-Based Photocatalysts

Photo-catalysis is a research field with broad applications in terms of potential technological applications related to energy production and managing, environmental protection, and chemical synthesis fields. A global goal, common to all of these fields, is to generate photo-catalytic materials able to use a renewable energy source such as the sun. As most active photocatalysts such as titanium oxides are essentially UV absorbers, they need to be upgraded in order to achieve the fruitful use of the whole solar spectrum, from UV to infrared wavelengths. A lot of different strategies have been pursued to reach this goal. Here, we selected representative examples of the most successful ones. We mainly highlighted doping and composite systems as those with higher potential in this quest. For each of these two approaches, we highlight the different possibilities explored in the literature. For doping of the main photocatalysts, we consider the use of metal and non-metals oriented to modify the band gap energy as well as to create specific localized electronic states. We also described selected cases of using up-conversion doping cations. For composite systems, we described the use of binary and ternary systems. In addition to a main photo-catalyst, these systems contain low band gap, up-conversion or plasmonic semiconductors, plasmonic and non-plasmonic metals and polymers.


Introduction
Heterogeneous photocatalysis uses semiconductors to generate charge carrier species from the absorption of light. These charge carriers can migrate to the surface of the photo-catalysts and transform chemical molecules in the context of chemical reactions concerning elimination of pollutants, generation of fuels or added value chemicals, microorganism inactivation, and others. All these chemical (and biological) processes compete with the recombination of charge, and the balance between these two types of processes controls the fate of charge carrier species and primarily determine photo-activity [1][2][3].
The most successful semiconductor used corresponds to titania. Titania can present at least three stable polymorphs: anatase, rutile and brookite. The first is considered the most active and has broad utility due to its good performance in all reaction tested, its wide availability, reduced cost and relatively limited effects in human health. Other interesting oxides correspond to zinc, tungsten, cerium, bismuth or most complex ones like perovskites, tungstates, bismutates, etc. Additional non-oxide semiconductors broadly utilized correspond to carbon nitride, graphene or polyoxometalates [1,[4][5][6][7][8][9][10][11]. All these systems share a main problem; they all can utilize a single range of sunlight wavelengths. Specifically, most of them can use UV or visible light and a few can profit from near infrared, however none of them can effectively (for example, visible light active bismutates cannot perform as titania Work carried to dope the ZnO oxide (wurtzite phase in most cases) is also of interest in photocatalysis. The physico-chemical situation is completely parallel to the titania case. Successful incorporation and concomitant increase of photoactivity have been observed, for example, using Al, Fe, Cu, Nd, and Ce [26][27][28][29]. Doping of other photocatalytic semiconductors is less studied although there are many examples such as the doping of bismuth oxide [30], thin oxide [31], cadmium sulfide [32] or of more complex formulations such as LaFeO3 [33].
Interestingly, some works are also devoted to use near-infrared wavelengths in addition to the UV and/or visible ones. Tm, Gd, Er and Ho (and combinations with other lanthanides such as Er/Yb) are cations specifically designed to increase activity under visible and near-IR illumination due to an up-conversion process that render UV or high-energy visible photons (all above ca. 380 nm) utilized by the anatase network. Specific cations (Like Pr and Nd) can also provide visible to UV upconversion. All these cations are usually utilized in relatively low concentrations (typically between 0.5 mol% and 3 mol%) and pure anatase and anatase plus rutile composite powders are commonly doped with these lanthanides [34,35]. Other semiconductors extensively explored in the field of upconversion though doping are, for example, BiVO4 [36] or Bi2WO4 [37] or CaF2 [38].
The Er case is the prototypical cation used for titania-based materials in the field of upconversion. Erbium-doped TiO2 materials showed good photoactivity for the liquid-phase degradation of phenol and methylene blue and the gas phase of toluene. The characterization results indicated that the presence of Er 3+ induces a progressive anatase cell expansion due to its incorporation in the TiO2 lattice. The best photocatalytic performance was attained for the samples with 2 at. % of Er 3+ irrespective of the chemical degradation reaction essayed. Er presence increases simultaneously UV and NIR activity, as schematically shown in Figure 2 (panels a and b). The first is based on the positive effect of Er doping ions acting as electron scavenger and decreasing charge recombination. The up-conversion luminescence process of Er 3+ also allowed us to profit in terms of the NIR range of the lamp and transferring energy in the UV range to the TiO2. This indicates that Er 3+ plays a significant role in the overall photocatalytic mechanism [39]. Er is commonly essayed in presence of Yb. The benefit is graphically explained in Figure 2c. Er and Yb co-doping titania (2 at. % Er and 0, 10, 15, or 20 at. % Yb), obtained by a modified hydrothermal process, was essayed on Interestingly, some works are also devoted to use near-infrared wavelengths in addition to the UV and/or visible ones. Tm, Gd, Er and Ho (and combinations with other lanthanides such as Er/Yb) are cations specifically designed to increase activity under visible and near-IR illumination due to an up-conversion process that render UV or high-energy visible photons (all above ca. 380 nm) utilized by the anatase network. Specific cations (Like Pr and Nd) can also provide visible to UV up-conversion. All these cations are usually utilized in relatively low concentrations (typically between 0.5 mol% and 3 mol%) and pure anatase and anatase plus rutile composite powders are commonly doped with these lanthanides [34,35]. Other semiconductors extensively explored in the field of up-conversion though doping are, for example, BiVO 4 [36] or Bi 2 WO 4 [37] or CaF 2 [38].
The Er case is the prototypical cation used for titania-based materials in the field of up-conversion. Erbium-doped TiO 2 materials showed good photoactivity for the liquid-phase degradation of phenol and methylene blue and the gas phase of toluene. The characterization results indicated that the presence of Er 3+ induces a progressive anatase cell expansion due to its incorporation in the TiO 2 lattice. The best photocatalytic performance was attained for the samples with 2 at. % of Er 3+ irrespective of the chemical degradation reaction essayed. Er presence increases simultaneously UV and NIR activity, as schematically shown in Figure 2 (panels a and b). The first is based on the positive effect of Er doping ions acting as electron scavenger and decreasing charge recombination. The up-conversion luminescence process of Er 3+ also allowed us to profit in terms of the NIR range of the lamp and transferring energy in the UV range to the TiO 2 . This indicates that Er 3+ plays a significant role in the overall photocatalytic mechanism [39]. Er is commonly essayed in presence of Yb. The benefit is graphically explained in Figure 2c. Er and Yb co-doping titania (2 at. % Er and 0, 10, 15, or 20 at. % Yb), obtained by a modified hydrothermal process, was essayed on photocatalytic degradation of phenol and Rose Bengal dyes under simulated solar radiation and using LED illumination of specific frequencies in the ultraviolet, green, red, and infrared regions. The 2% Er 10%Yb co-doped TiO 2 catalyst exhibited the best phenol and Rose Bengal photo-degradation under UV illumination. However, using green, red, and infrared illumination no significant activity was observed [40]. The Er, Yb, and Er-Yb titania powders were tested under visible light excitation showing that catalysts can work with illumination Molecules 2020, 25, 4008 5 of 27 wavelengths up to ca. 475 nm and that Yb at 1 at. % rendered the best activity [41]. Thus, no obvious improvement over Er-doped materials appears in the case of Er-Yb co-doped titania photocatalysts. Also a Er-Sm co-doped anatase-rutile composite (mixed anatase-rutile with dominant presence of the first) catalyst have been analyzed in the literature [42]. The catalyst having a 3/0.6 mol% of Sm/Er maximizes activity for degradation of the acid blue 113 dye working at pH 2. Sm presence triggers the decrease of anatase band gap to reach a value of 2.8 eV, opening the fruitful use of visible photons. At the same time, Er is responsible for an up-conversion process which generates UV from IR photons, providing energy to the anatase powder.
Molecules 2020, 25, x FOR PEER REVIEW 5 of 28 photocatalytic degradation of phenol and Rose Bengal dyes under simulated solar radiation and using LED illumination of specific frequencies in the ultraviolet, green, red, and infrared regions. The 2% Er 10%Yb co-doped TiO2 catalyst exhibited the best phenol and Rose Bengal photo-degradation under UV illumination. However, using green, red, and infrared illumination no significant activity was observed [40]. The Er, Yb, and Er-Yb titania powders were tested under visible light excitation showing that catalysts can work with illumination wavelengths up to ca. 475 nm and that Yb at 1 at. % rendered the best activity [41]. Thus, no obvious improvement over Er-doped materials appears in the case of Er-Yb co-doped titania photocatalysts. Also a Er-Sm co-doped anatase-rutile composite (mixed anatase-rutile with dominant presence of the first) catalyst have been analyzed in the literature [42]. The catalyst having a 3/0.6 mol% of Sm/Er maximizes activity for degradation of the acid blue 113 dye working at pH 2. Sm presence triggers the decrease of anatase band gap to reach a value of 2.8 eV, opening the fruitful use of visible photons. At the same time, Er is responsible for an up-conversion process which generates UV from IR photons, providing energy to the anatase powder.
Molecules 2020, 25 Additional research towards the full use of the solar spectrum explored the co-doping of titania materials having Er and other non-luminescent cations. Er was used together with W to dope anatase nanostructured materials. In this case, nanostructured (ca. 10 nm) anatase powders were synthesized in presence of Er (2 mol%) and W (ca. 15 mol%) [43]. The structural investigation demonstrates the substitutional replacement of Ti by both cations with presence of characteristic Er-O-W contacts in the co-doped system. The system showed outstanding performance against Gram-positive and Gram-negative bacteria. A joint use of EPR and photoluminescence rendered information about charge carrier species generated after illumination. Activity showed an acute dependence of the excitation wavelength due to a different physical origin. Below ca. 550 nm (so, in the UV or initial (c) Figure 2. Proposed electronic mechanism for Er 3+ doping of TiO 2 occurring under UV excitation (a) and near-infrared (NIR) excitation (b). Reprinted with permission from [38] Additional research towards the full use of the solar spectrum explored the co-doping of titania materials having Er and other non-luminescent cations. Er was used together with W to dope anatase nanostructured materials. In this case, nanostructured (ca. 10 nm) anatase powders were synthesized in presence of Er (2 mol%) and W (ca. 15 mol%) [43]. The structural investigation demonstrates the substitutional replacement of Ti by both cations with presence of characteristic Er-O-W contacts in the co-doped system. The system showed outstanding performance against Gram-positive and Gram-negative bacteria. A joint use of EPR and photoluminescence rendered information about charge carrier species generated after illumination. Activity showed an acute dependence of the excitation wavelength due to a different physical origin. Below ca. 550 nm (so, in the UV or initial visible region) a strong decrease of recombination and generation of surface local entities promoting the formation of hydroxyl radicals were directly ascribed to the substitutional replacement of Ti ions of the anatase structure. For most of the visible (above 550 nm) as well as for infrared wavelengths up to ca. 1000 nm, additional surface sites linked with W-Er surface species were responsible for generation of hot electron species. The two types of photo-related mechanisms inactivate the microorganisms and render a material able to work efficiently in the whole UV-visible-near IR spectral range [43]. Another case study corresponds to Er-Ce co-doping of titania. In this case, the Er:Ce atomic ratio (Er 0.5 mol% and Ce 0.1, 0.2 and 0.3 mol%) was varied. The materials were employed for methylene orange photo-degradation and photocatalytic disinfection (S. aureus and E. coli) tests. In all photocatalytic tests, the sample Er/Ce = 0.5/0.2, calcined at 800 • C, exhibited the highest photocatalytic performances. The existence of Er ions is thought to successfully turn the near-infrared radiation into visible region, which is easier to be absorbed by the co-doped TiO 2 material. Meanwhile, the addition of Ce ions can effectively extend spectral response range and inhibit the recombination of electrons and holes, enhancing the photocatalytic disinfection activity of co-doped TiO 2 [44].
The utilization of visible and, critical considering the goal of this contribution, sunlight photons has been also deeply investigated using non-metal (also called anion) doping. An interesting approach attempted to control the formation of the Ti-N bond in the catalyst using N-containing-type ligands (2-methoxyethylamine, tetramethylethylenediamine and 1,2-phenylenediamine) in the initial Ti precursor subjected to hydrolysis in a microemulsion medium and posterior calcination [45,46]. The method renders anatase materials with (size in the 8-14 nm), tested in the photo-degradation of methylcyclohexane. Light absorption into the visible region was achieved in all cases, but activity was maximized using the tetramethyl-ethylenediamine ligand. Activity under solar illumination was associated with N incorporation to anatase lattice and presence of charge neutrality vacancies. A multi-edge X-ray absorption study of the catalysts provided insights into the charge neutrality process, demonstrating the existence of cationic vacancies as well as strongly disturbed middle range order with absence of typical Ti (III) states. Optimum activity was found to be associated with an optimum N/Ti ratio of ca. 0.1. Higher N content leads to interacting defects affecting negatively activity by an increase of the charge recombination [47]. A combination of microemulsion and hydrothermal synthesis procedures utilized different (organic/inorganic molecule) sources in the aqueous phase to dope titanium oxide with nitrogen. Materials were tested for Rhodamine B (RhB) dye and 2,4-dichlorophenol elimination. Maximum activity was obtained with a trimethylamine precursor used as nitrogen source. Band gap modification and charge recombination decrease were detected as a result of nitrogen incorporation. Both render positive activity effects for a (synthesis) N/Ti ratio of 2 [48]. More simple preparation procedures consist of thermal treatment of titania oxo-hydroxide precursor(s) in ammonia, hydrazine, nitrous oxide and/or other nitrogen-containing gases or liquids [49]. Similarly, other oxides such as ZnO, perovskites and many others have been examined in the context of nitrogen doping [50]. In general, and as summarized in references [1,49], nitrogen doping is a rather complex phenomenon from a structural and electronic point of view. Several chemical species (N at anion position, NO, NH x , CN at interstitial and surface positions, and others) are present in the solid irrespective of the preparation procedure leading to a variety of situations. However, it appears that, essentially, such N-containing species create different localized defects states [1,[45][46][47][48][49][50]. Of course, this depends on the loading, as it grows localized states located near the valence and conduction bands of parent structure can coalesce with such bands, changing from localized to delocalized structure. However, it appears that in non-covalent oxides such as titanium or zinc oxides a high level of nitrogen, above ca. 2-3 at. %, is required for such coalescence and thus mostly localized states are obtained in reported publications [1,49,50]. Figure 2 depicts a summary of the (main) chemical species and corresponding (localized) electronic effects affecting activity. Simultaneous use of UV and visible photons is ascribed to a combination of effects related to the new states near the conduction band (absorption of visible light photons) and, at specific N/Ti ratios, a decrease of charge recombination, obtained irrespective of the illumination wavelength. Other species may also contribute to enhance the photo-activity but the corresponding structure-activity links are yet to be firmly established. The combination of N and cations such as W was essayed, and the study of the corresponding preparation procedure and chemical species present in the solid thoroughly detailed [51]. Nanostructured (4-10 nm) anatase powders were obtained having a N content up to 1.5 at. % and W up to ca. 22 at. and tested in the partial oxidation of toluene and styrene. Analysis of the effect of calcination temperature in the 400-600 • C range provided evidence of the activity maximization at the lower calcination treatment, irrespective of the illumination wavelength [52]. A N/W 0.1/10 at. % content of the anatase phase optimized activity. This was ascribed to a combined effect of the decrease of the band gap energy and the concomitant increase of radical hydroxyl-type species (in turn derived from a decrease of charge recombination).
The cases of halides [53][54][55][56] is relatively simple. Fluoride incorporation at the bulk of anatase generates Ti 3+ species on the gap for charge compensation ( Figure 2). On the other hand, F presence at the surface has a strong effect in the primary particle shape of anatase, favoring the exposure of the (001) plane [57][58][59]. S doping has also been explored and, contrarily, is a structurally complex system. To a first approximation, Sulphur doping parallels the complexity of N-containing one in terms of the chemical species potentially present as well as electronic effects. S doping usually considers anionic (S 2− ; S 2 2− ) species [60] and cationic (S 4+ ; S 6+ ) substitutional/interstitial-type [61] species, in addition to, at least, sulfate surface species. S stabilizes the anatase polymorph (retarding rutile appearance upon calcination), increases light absorption and, in both anionic and cationic positions, reduces charge carrier recombination. Figure 3 summarizes the electronic situation for the mentioned cases. Sulphur combination with Fe has been shown to be particularly effective for UV and visible light utilization in photo-catalysis [62]. C is another complex case, experimental approaches indicate the presence of surface carbonate and carbonaceous species, as well as lattice-bound carbon species [63,64]. Lattice positions can be anionic and cationic substitutional positions as well as interstitial ones. Their electronic effects are detailed in Figure 3. Apparently, most efficient photocatalysis is achieved in presence of localized states near the valence band. This similarity with nitrogen doping is not only a characteristic of TiO 2 based catalysts but it is apparently the case for ZnO [65]. Co-doping of C and Fe has been also essayed to obtain single phase nanostructured (primary particle size of 12-16 nm) anatase powders [66]. C atoms were detected at substitutional and interstitial positions of the anatase while Fe occupied Ti cation lattice positions. Materials were tested for malachite green photo-degradation. Authors observed maximum activity using a catalyst having a doping content of ca. 8/2 C/Fe wt.%. In these co-doped samples, carbon is responsible for appearance of localized states near the conduction band while Fe has multiple roles, particularly affecting capture electrons and decrease recombination of charge carriers. The cooperation of the two alien atoms opens a pathway for visible light utilization and to optimize the charge carrier fraction utilized to oxidize the target molecule. The co-doping of zinc oxide is also frequently investigated, and the C and Fe pair is a case under investigation. An Fe content close to 2.1 wt.% leads to maximum activity for 2,4,6-trichlorophenol elimination under visible light illumination. For this formulation, carbon and Fe ions trigger the appearance of localized levels near valence and conduction bands, respectively, facilitating visible light absorption and improving activity with respect to single-doped and bare oxide reference materials [67]. mentioned cases. Sulphur combination with Fe has been shown to be particularly effective for UV and visible light utilization in photo-catalysis [62]. C is another complex case, experimental approaches indicate the presence of surface carbonate and carbonaceous species, as well as lattice-bound carbon species [63,64]. Lattice positions can be anionic and cationic substitutional positions as well as interstitial ones. Their electronic effects are detailed in Figure 3. Apparently, most efficient photocatalysis is achieved in presence of localized states near the valence band. This similarity with nitrogen doping is not only a characteristic of TiO2 based catalysts but it is apparently the case for ZnO [65]. Co-doping of C and Fe has been also essayed to obtain single phase nanostructured (primary particle size of 12-16 nm) anatase powders [66]. C atoms were detected at substitutional and interstitial positions of the anatase while Fe occupied Ti cation lattice positions. Materials were tested for malachite green photo-degradation. Authors observed maximum activity using a catalyst having a doping content of ca. 8/2 C/Fe wt.%. In these co-doped samples, carbon is responsible for appearance of localized states near the conduction band while Fe has multiple roles, particularly affecting capture electrons and decrease recombination of charge carriers. The cooperation of the two alien atoms opens a pathway for visible light utilization and to optimize the charge carrier fraction utilized to oxidize the target molecule. The co-doping of zinc oxide is also frequently investigated, and the C and Fe pair is a case under investigation. An Fe content close to 2.1 wt.% leads to maximum activity for 2,4,6-trichlorophenol elimination under visible light illumination. For this formulation, carbon and Fe ions trigger the appearance of localized levels near valence and conduction bands, respectively, facilitating visible light absorption and improving activity with respect to single-doped and bare oxide reference materials [67].

Composite Photocatalysts
Composite photocatalysts can have a significant number of different families. A first one considers the coupling of two (or several) semiconductors. Using titania as the base component we  Figure 3. Schematic representation of the electronic effects generated by non-metal doping in anatase-based systems.

Composite Photocatalysts
Composite photocatalysts can have a significant number of different families. A first one considers the coupling of two (or several) semiconductors. Using titania as the base component we can distinguish between systems oriented to couple titania with visible or infrared oriented components. A second family can couple titania with metals and is particularly oriented to use the surface plasmon resonance to enhance simultaneously UV and visible (sometimes near IR) capabilities of the photocatalyst. A third family utilizes polymers as the base component of a composite system. In all cases, the interface among components plays a critical role in favoring activity [68].
Considering the use of UV and visible light, main examples of the first family of TiO 2 -based samples present a positive photocatalytic response (higher activity than the bare titania reference). Such an effect has been achieved by a well-controlled interaction of titania with minor oxide entities such as SiO 2 [69,70], CuO x [71,72], NiO [73], ZnO [71,74], Bi 2 O 3 [75][76][77], CeO x [77][78][79], or WO 3 [80]. FeO x -containing semiconductors are also actively investigated however the behavior of such systems combine frequently photocatalysis with photo-Fenton [81]. More complex formulations consider the combination of titania with, for example, heteropolyacids [82,83], vanadates such as BiVO 4 [84,85] or complex oxides such as CuNiOx [86] and FeAlO 3 [87]. Similar catalysts have been studied for ZnO-based materials. More specific are those having two Zn-based semiconductors such as ZnWO 4 [88] or ZnFe 2 O 4 [89] combinations with ZnO. In these cases, to a first rough approximation, the UV activity is controlled by titania (or ZnO) and can be improved if charge separation takes place between the two components after light absorption. This requires specific arrangements of the conduction and valence bands of the components, being among the most successful those of type-II (which separates physically electron and holes created in both components) or Z-type schemes (which facilitates the selective annihilation taking place between electrons of one component and holes of the other). The exact contact between titania and the above-mentioned second components is strongly size-dependent, and current information is relatively limited [1,17]. Visible activity is, on the other hand, usually achieved by the light excitation of the second component although the different (local) structure of titania and the interface between components can play an active catalytic role.
As an illustrative example of the situation we highlight a study using three of the aforementioned oxides (CuO, CeO 2 and Bi 2 O 3 ) present on the surface of an active (and dominant component on percentage) anatase TiO 2 component [77]. Under UV, activity was optimized at somewhat low concentrations (x mol% below 2.5 mol%; Figure 4A). Under sunlight-type irradiation, the maximization of activity required catalysts with higher concentrations of the surface oxides (2.5 mol% for CuO and 5 mol% for CeO 2 ; Figure 4B). Although an enhancement of the absorption of visible light photons was confirmed using optical spectroscopies, the Bi 2 O 3 -TiO 2 system did not improve (for all contents) the activity of the pure TiO 2 reference. Figure   A singular contribution makes a careful comparison between doped and composite Wcontaining TiO2 anatase catalysts [90]. This would attempt to compare the difference of surface tungsten species obtained in a pure doped system with those deposited onto the titania oxide. Figure  5 summarizes information rendered by electron diffraction for doped (W-TiO2) and composite samples (WO3/TiO2). The physico-chemical analysis of the catalysts probes the differences in the W- A singular contribution makes a careful comparison between doped and composite W-containing TiO 2 anatase catalysts [90]. This would attempt to compare the difference of surface tungsten species obtained in a pure doped system with those deposited onto the titania oxide. Figure 5 summarizes information rendered by electron diffraction for doped (W-TiO 2 ) and composite samples (WO 3 /TiO 2 ). The physico-chemical analysis of the catalysts probes the differences in the W-containing entities in these two types of samples. The dark field microscopy images included in Figure 5 identified the specific geometrical/structural location of W in doped and composite samples, showing the structural differences of having isolated atoms located at titania surface positions (doped samples) from those where always W-O-W (clustering) is obtained (composite samples). The activity of the doped/composite samples having equal W/Ti ratio is also presented in Figure 5. Strong differences are observed between the two types of samples, a fact that emerges from the different handling of light and surface properties [90]. Combination of titania with carbon containing semiconductors such as carbon nitride [91][92][93][94][95] and graphene [96][97][98][99] or graphyne-type materials [100][101][102] can also be highlighted in the context of the UV-visible combination. Many oxides, for example, CeO2 were also tested in combination with carbon layers [103] or carbon nitride [104]. Considering pure anatase, the interaction with carbon nitride has been analyzed but conflicting results are present in the literature. As reviewed in ref. [4], both type II (with electrons transferred to titania and holes to carbon nitride) and Z-scheme (with Combination of titania with carbon containing semiconductors such as carbon nitride [91][92][93][94][95] and graphene [96][97][98][99] or graphyne-type materials [100][101][102] can also be highlighted in the context of the UV-visible combination. Many oxides, for example, CeO 2 were also tested in combination with carbon layers [103] or carbon nitride [104]. Considering pure anatase, the interaction with carbon nitride has been analyzed but conflicting results are present in the literature. As reviewed in ref. [4], both type II (with electrons transferred to titania and holes to carbon nitride) and Z-scheme (with electrons from titania and holes from carbon nitrate suffering annihilation) junction appears to operate under UV illumination. No obvious physico-chemical grounds have been presented in order to justify such difference. Under visible illumination it appears that charge separation takes place with electrons going from carbon nitride to titania. Operation under sunlight improves the parent systems and this has been particularly ascribed to the electronic contact between the materials, as well as other positive effects of carbon nitride incorporation into the composite and related to morphological and adsorption properties [91][92][93][94][95]. In the case of graphene-titania, similar positive effects have been described to consider the higher activity displayed with respect to the parent reference systems [96][97][98]. An interesting study analyzed the specific interaction of shape-controlled anatase particles exposing specific surfaces to graphene [105]. As shown in Figure 6, the control of the shape of the anatase nanoparticles triggers the contact of the anatase with the carbon nitride support using specific surfaces planes, (101), (001) and (100). Activity is strongly promoted by the presence of graphene. Activity is shown to follow the order (100) > (101) > (001), which is not the activity order for pure anatase samples. An improved charge transfer for the case of the (100) surface due to the generation of close Ti-C carbon contacts is claimed to be the main reason for the high activity of the composite system. Again, this proves that the contact between phases is strongly dependent on local order details, which are not easily predicted using current knowledge. The detailed information at nanometric level may permit us to understand the effect of the interface on charge handling and would thus allow us to rationalize the charge behavior of the composites of titania and carbon-containing materials.
Molecules 2020, 25, x FOR PEER REVIEW 12 of 28 morphological and adsorption properties [91][92][93][94][95]. In the case of graphene-titania, similar positive effects have been described to consider the higher activity displayed with respect to the parent reference systems [96][97][98]. An interesting study analyzed the specific interaction of shape-controlled anatase particles exposing specific surfaces to graphene [105]. As shown in Figure 6, the control of the shape of the anatase nanoparticles triggers the contact of the anatase with the carbon nitride support using specific surfaces planes, (101), (001) and (100). Activity is strongly promoted by the presence of graphene. Activity is shown to follow the order (100) > (101) > (001), which is not the activity order for pure anatase samples. An improved charge transfer for the case of the (100) surface due to the generation of close Ti-C carbon contacts is claimed to be the main reason for the high activity of the composite system. Again, this proves that the contact between phases is strongly dependent on local order details, which are not easily predicted using current knowledge. The detailed information at nanometric level may permit us to understand the effect of the interface on charge handling and would thus allow us to rationalize the charge behavior of the composites of titania and carbon-containing materials. Additional composite systems relay in the combination of the UV-oriented TiO2 and infrared absorbing semiconductors. Sulfides such as MoS2 or In2S3 have been used in this context [106,107]. Regarding oxides, we can highlight the cases of Ag2O [108], and WOx [109,110]. These systems and particularly the latter are real, full-spectrum catalysts, with utilization of the UV-visible-nearIR electromagnetic range. In addition, WOx-TiO2 has been tested in ternary configurations with graphene oxide in order to enhance activity upon all illumination conditions [111]. Defective W(VI) oxides are known to present a strong absorption capability along visible and infrared regions, and Additional composite systems relay in the combination of the UV-oriented TiO 2 and infrared absorbing semiconductors. Sulfides such as MoS 2 or In 2 S 3 have been used in this context [106,107]. Regarding oxides, we can highlight the cases of Ag 2 O [108], and WO x [109,110]. These systems and particularly the latter are real, full-spectrum catalysts, with utilization of the UV-visible-nearIR electromagnetic range. In addition, WO x -TiO 2 has been tested in ternary configurations with graphene oxide in order to enhance activity upon all illumination conditions [111]. Defective W(VI) oxides are known to present a strong absorption capability along visible and infrared regions, and are also photocatalytically active. In Figure 7 it is shown that the W-Ti composite excited under near infrared (750 nm) light combines thermal and light-related effects. Thermal effects are not as strong as in the pure WO x reference but they clearly contribute to photocatalytic activity. This appears as a mixture of thermal and light effects due to the non-radiative and radiative de-excitation taking place under visible and IR illumination conditions. The effect is not a simple sum and a clear synergy comes out from the analysis of Figure 7 [110]. Such a behavior was also present in Ru-RuO x core-shell structures supported in anatase TiO 2 [112]. The heat-light synergy is a complex phenomenon which is observed the presence of plasmonic type components but also adequate handling of light-heat transformation through the phonons of the solids as well as surface chemical species. Additionally, non-plasmonic materials could also provide the basis of thermo-photo catalysts using infrared light as heat and/or light primary sources. Ceria-based materials constitute a paradigmatic example, with thermo-photo activity mostly related to defect chemistry, although the details are essentially unknown [113][114][115][116].
Molecules 2020, 25, x FOR PEER REVIEW 13 of 28 infrared (750 nm) light combines thermal and light-related effects. Thermal effects are not as strong as in the pure WOx reference but they clearly contribute to photocatalytic activity. This appears as a mixture of thermal and light effects due to the non-radiative and radiative de-excitation taking place under visible and IR illumination conditions. The effect is not a simple sum and a clear synergy comes out from the analysis of Figure 7 [110]. Such a behavior was also present in Ru-RuOx core-shell structures supported in anatase TiO2 [112]. The heat-light synergy is a complex phenomenon which is observed the presence of plasmonic type components but also adequate handling of light-heat transformation through the phonons of the solids as well as surface chemical species. Additionally, non-plasmonic materials could also provide the basis of thermo-photo catalysts using infrared light as heat and/or light primary sources. Ceria-based materials constitute a paradigmatic example, with thermo-photo activity mostly related to defect chemistry, although the details are essentially unknown [113][114][115][116].  Other composite systems relay in the used of solid up-converters. An illustrative example concerns the NaYF4:Yb 3+ , Tm 3+ @TiO2 core-shell structured photocatalyst. The characterization results showed that the core-shell structured composite consisted on (hexagonal phase) NaYF4:Yb 3+ , Tm 3+ microrods and anatase TiO2 nanosheets with exposed high-reactive {001} facets (Figure 8). The new  Other composite systems relay in the used of solid up-converters. An illustrative example concerns the NaYF4:Yb 3+ , Tm 3+ @TiO 2 core-shell structured photocatalyst. The characterization results showed that the core-shell structured composite consisted on (hexagonal phase) NaYF 4 :Yb 3+ , Tm 3+ microrods and anatase TiO 2 nanosheets with exposed high-reactive {001} facets (Figure 8). The new photocatalyst gives higher photocatalytic activity than the (components) physical mixture and pure TiO 2 for phenol and RhB elimination under NIR and (to a lesser extent) simulated sunlight irradiation. The authors proposed a mechanism to explain the enhancement in the photoactivity reached with the NaYF 4 :Yb 3+ , Tm 3+ @TiO 2 photocatalyst, as summarized in the schematic illustration presented in Figure 8. In this figure, the up-converter supplies UV and visible (blue) photons to the titania counterpart [117]. Other relatively similar works are rhombic hierarchical YF 3 /TiO 2 [118], β-NaYF 4 :Yb 3+ ,Tm 3+ /Er 3+ -TiO 2 [119], or NaYF 4 :Yb +3 ,Nd +3 @ TiO 2 [120] composite systems.
Molecules 2020, 25, x FOR PEER REVIEW 14 of 28 presented in Figure 8. In this figure, the up-converter supplies UV and visible (blue) photons to the titania counterpart [117]. Other relatively similar works are rhombic hierarchical YF3/TiO2 [118], β-NaYF4:Yb 3+ ,Tm 3+ /Er 3+ -TiO2 [119], or NaYF4:Yb +3 ,Nd +3 @ TiO2 [120] composite systems.  On the other hand, the up-conversion core catalysts have not only been combined with TiO2 but also with other materials to obtain hybrid or composite ternary systems. Up-conversion/C-TiO2 ternary composite systems have been studied in detail. In a first work [121], a (Yb 3+ ,Er 3+ )-NaYF4/C-TiO2 composite system photoactivity was evaluated for NOx destruction reaction under UV, visible and near-infrared light illumination conditions. The results showed that when the C-TiO2 photocatalyst was combined with the (Yb 3+ ,Er 3+ )-NaYF4 up-conversion phosphor, the visible On the other hand, the up-conversion core catalysts have not only been combined with TiO 2 but also with other materials to obtain hybrid or composite ternary systems. Up-conversion/C-TiO 2 ternary composite systems have been studied in detail. In a first work [121], a (Yb 3+ ,Er 3+ )-NaYF 4 /C-TiO 2 composite system photoactivity was evaluated for NOx destruction reaction under UV, visible and near-infrared light illumination conditions. The results showed that when the C-TiO 2 photocatalyst was combined with the (Yb 3+ ,Er 3+ )-NaYF 4 up-conversion phosphor, the visible absorption of C-TiO 2 was significantly improved up to 900 nm, presenting a nice correlation with the photoluminescence spectrum of (Yb,Er)-NaYF 4 excited with 980 nm. For this reason, the (Yb 3+ ,Er 3+ )-NaYF 4 /C-TiO 2 composite presented excellent deNOx ability not only under the irradiation of visible and UV lights but also NIR light, being much superior to those of pure C-TiO 2 , P25 and even the (Yb 3+ ,Er 3+ )-NaYF 4 /N-TiO 2 composite. In the second work [122], the authors mixed the blue color (Yb 3+ ,Tm 3+ )-NaYF 4 (named B-UP), green color (Yb 3+ ,Er 3+ )-NaYF 4 (named GUP) and red color (Yb 3+ ,Er 3+ )-Y 2 O 3 /YOF (named R-UP) up-conversion phosphors with C-TiO 2 using a weight ratio of 1:1 The photocatalytic activities of the composites were evaluated in the degradation of RhB and the elimination of NO gas under NIR light irradiation. According to photocatalytic results, the photonic efficiency under infrared light was much higher than the corresponding observables obtained under UV and visible light. The green light emitting up-conversion phosphor-C-TiO 2 composite presented superior photocatalytic performance over blue and red ones.
Another family of materials concerns the anatase-based composite systems with a second plasmonic-type component. Most typically plasmonic components consist of metals; we previously mentioned those based in semiconductors, such as tungsten-based ones. A plasmonic-based catalytic system based in metals is mostly used to profit from UV and visible light, although here we will show examples that can also profit from near infrared wavelengths. Under UV illumination, titania and most typical semiconductors can improve charge separation through the electron storage capacity of the metal and the subsequent beneficial effects connected with the higher lifetime of hole-related species located at the semiconductor. Under visible illumination, the metal is the component able to absorb light and electrons can be transferred to the semiconductor phase [1,6]. Of course, metals are also frequently utilized in multi-component catalysts (and not only with a main UV-absorber photocatalyst) in order to efficiently harvest the full solar light spectrum. The most utilized (plasmonic or not) metals as photo-catalytic co-catalysts are Au, Ag, Pt, Pd, or Cu as well as their binary combinations [1,5,123,124].
Considering metals gold is a classical plasmonic-type choice. Asymmetric Janus nanostructures containing a gold nanocage (NC) and a carbon-titanium oxide hybrid nanocrystal (AuNC/(C-TiO 2 )) exhibited 3.2 times higher photoactivity than that obtained with the C-TiO 2 in the photocatalytic aerobic oxidation of isopropanol under visible light. Electromagnetic field simulations and EPR results indicate that plasmon-photon coupling is largely amplified at the interface between the AuNC and C-TiO 2 components, leading to the enhanced generation of energetic hot electrons utilized in the photocatalytic reaction [125]. Nanoparticles of gold over titania also showed exceptional activity in bio-alcohol reforming under UV and solar light conditions, optimizing activity for sizes near 5-6 nm [126]. An interesting ternary system using this metal is the NaYF 4 (Yb 3+ /Er 3+ )-TiO 2 -Au [127,128]. In one work, a series of Au decorated NYF@TiO 2 core@porous-shell microspheres (0.5, 1, 2, 3 wt.% Au) were presented. The photocatalytic efficiency of these new nanohybrid catalysts toward methyl orange (MO) degradation was examined, and the significant enhancement was observed with respect to the benchmark photocatalyst P25, as well as NYF and NYF@TiO 2 samples. The highest MO degradation was obtained with the material with 1 wt.% of Au under NIR and solar irradiation. The enhanced activity was attributed to synergistic effects from nanocomponents arranged into the nanostructured architecture in such a way that favors the efficient charge/energy transfer among nanocomponents and largely reduced charge recombination [127]. Recently, the (NaYF 4 :Yb 3+ /Er 3+ )-Au/TiO 2 nanotube-type material was synthesized and its photocatalytic activity compared with the TiO 2 NTs (nanotubes) and Au/TiO 2 for the RhB degradation under NIR illumination. The results indicated that the up-converter-Au/TiO 2 NTs sample exhibited outstanding photocatalytic activity in the degradation of RhB but no obvious degradation was observed in the presence of TiO 2 NTs and Au/TiO 2 NTs. These results indicate that NIR light can be exclusively utilized by (NaYF 4 :Yb 3+ /Er 3+ )-Au/TiO 2 NTs [128].
Silver is another plasmonic metal with frequent utilization in the field of photocatalysis. A series of Ag-TiO 2 photocatalysts were evaluated for phenol degradation under visible irradiation. Samples always contained a combination of Ag metallic and Ag + chemical states. Optimum activity was reached using a silver loading of 6.5 mol% (measured as AgNO 3 used during the preparation stage). Such optimum was correlated with the maximization of the amount of silver in Ag 0 form. More specifically, the authors suggested that the activity improvement connects with the presence of silver metal (due to enhancing the electron-hole separation and surface plasmon resonance as well as the presence of surface carbon working as a light sensitizer) [129]. Zerovalent metallic silver nanoparticles with hemispherical shape were observed in a series of g-C 3 N 4 /AgX (X = 2, 5, 10 and 12 wt.% of Ag) materials. The best photoactivity was obtained with the sample with 10% of Ag, improving the performance of the bare carbon nitride by ca. 2-fold for degradation of dyes. In a subsequent work, the g-C 3 N 4 /Ag10% material was the base for a ternary catalyst with MoS 2 quantum dots. An enhanced photocatalytic activity was observed for the hybrid photocatalyst. This was ascribed to the charge handling Z-scheme taking place in the system, with Ag nanoparticles acting as the charge separation center [130]. A ternary system containing silver has been extensively studied. A different ternary system is a NaYF 4 :Yb 3+ , Tm 3+ @TiO 2 /Ag core@comby shell nanostructure. The R6G dye degradation results demonstrated that the composite exhibits excellent photocatalytic activity as the up-converter core can efficiently converts NIR light into UV light [131]. NIR and UV-visible light induced photocatalytic activity was observed for a NaYF 4 :Yb 3+ ,Tm 3+ @TiO 2 /Ag composite. The nanocomposite showed photocatalytic activity for Rhodamine B degradation under full solar irradiation. Corresponding activity measurement appeared to increase UV and visible light activity with respect to photocatalyst(s) based on Ag-titania. The enhancement was interpreted with the help of photoluminescence and ascribed to the NIR light influence in the overall photocatalytic reaction taking place in the NaGdF 4 :Yb 3+ : Er 3+ /Ag/TiO 2 composite [132].
Closely related to the above described silver-containing materials are Ag/AgX/semiconductor ternary materials. The silver coupling with a silver halide has been subjected to many investigations. As an example, an efficient and stable visible-light-driven Ag/AgX/graphene oxide, GO, (X = Br, Cl) plasmonic photocatalyst was assembled. The XPS results confirmed the existence of metallic Ag 0 in the Ag/AgX/GO hybrid nanocomposites with a surface molar ratio Ag 0 to Ag + of 1:16. Enhanced photocatalytic performance for the photodegradation of MO dye under visible-light illumination was shown by these materials with respect to Ag/AgX references. This could be attributed to the high adsorptive capacity of Ag/AgX/GO, the smaller size of Ag/AgX "nanoparticle" in the hybrid nanocomposites, the reinforced charge transfer, and the suppressed recombination of electron/hole pairs caused by the Ag 0 presence in Ag/AgX/GO [133]. The Ag/AgX couple was also supported on other semiconductors. Presence of 10-20 nm Ag 0 within Ag@AgCl quantum dots (QDs) were observed to be evenly dispersed on the surface of Bi 2 WO 6 . The Ag@AgCl (20 wt.%)/Bi 2 WO 6 sample exhibited the best photocatalytic activity, degrading 97.6% of rhodamine B (RhB) after irradiation for 2 h, which was 1.33 times and 1.32 times higher than that of Ag@AgCl and Bi 2 WO 6 photocatalysts, respectively. This was attributed to the excellent photocatalytic activity due to the synergetic effect of Bi 2 WO 6 , AgCl, and Ag nanoparticles [134]. Ag/AgBr/TiO 2 composite catalysts were tested for elimination of liquid phase aqueous phenol and gas-phase acetaldehyde. The composite showed an efficient photo-generated charge transfer between AgBr and TiO 2 under both UV-visible or visible illumination conditions. This in turn facilitated charge separation and the enhancement of the activity [135]. Finally, Ag/AgX/SrTiO 3 (X = Cl, Br) plasmonic photocatalysts were prepared by microemulsion and metallic Ag generated after a subsequent irradiation step. The degradation of MO and RhB dyes was essayed under visible light illumination, with the system containing AgBr showing higher activity. The enhanced activity was ascribed to the active role played by the AgBr component working together with the surface plasmon resonance of the Ag nanoparticles [136].
In addition, Pt has attracted attention in terms of using metal as a second component in composite catalysts. Platinum does not present (at least for nanosized range nanoparticles) a pure plasmonic optical behavior like the above-mentioned metals, but it is broadly used in the context of utilizing UV and visible light. Metallic Pt nanoparticles (3-5 nm) deposited on the surface of a commercial TiO 2 (Fluka) showed good activity for 2-propanol photo-degradation. Presence of the metal increased the activity ca. 1.6 times with respect to bare oxide. The Pt role was twofold, firstly it provides adsorption sites for 2-propanol and secondly, it acts as electron sink to facilitate separation of charge carrier species [137]. In other work, Pt nanoparticles supported over a N-doped TiO 2 were investigated, particularly the effects of the Pt loading content and pH of the (methanol/water) reaction medium on the performances of the photocatalysts for hydrogen evolution. The results showed that the addition of Pt onto the TiO 2−x N x surface (optimum loading of 0.2 wt.%) can increase the photocatalytic reaction and enhance hydrogen evolution. The photocatalytic reaction appears to be favored in the neutral pH range [138]. A rather nice contribution analyzed the catalytic effect of several variables such as the amount of Pt precursor, TiO 2 properties, deposition method (reverse microemulsion and wet incipient impregnation) and reducing agent on size, distribution, and chemical state of deposited Pt nanoparticles. XPS results confirmed that samples prepared by microemulsion showed much higher binding energy values for platinum than the other preparation method. Degradation of phenol under UV-visible illumination was shown to depend on Pt particle size. Optimum particle size and maximization of activity was achieved using the microemulsion method [139]. Interestingly, Pt can be deposited over anatase TiO 2 selectively over specific surface planes (like (101)), favoring specific reactions like hydrogen production [140]. Pd promotion of TiO 2 activity was also investigated [141]. The work analyzed the control of the metal particle size and showed that an average particle size of 2.4 nm improves activity significantly with respect to bare TiO 2 , particularly under visible light [141].
Bimetallic particles have also been utilized in composite materials in order to add visible and near infrared capabilities to the typical UV of the main semiconductors such as titania. Gold is present in a significant number of contributions. Bimetallic Ag/Au modified-titanium oxide photocatalysts improved the phenol photo-decomposition performance of monometallic references, obtaining the highest reaction rates with the samples Ag/Au-TiO 2 _4 and Ag/Au-TiO 2 _5 which contain different Au/Ag ratios (1.5/0.5 and 1.5/4.5 respectively) supported over the so-called "TiO 2 _4" (mixture of rutile and anatase) and "TiO 2 _5" (rutile) oxide solids, respectively [142]. Bimetallic (Au/Pt) nanoparticles were also prepared on titania using a microemulsion procedure. Optimum phenol degradation was achieved with the sample calcined at 450 • C with an Au/Pt ratio of 0.5/0.1 mol%. Size-controlled Au/Pt nanoparticles together with a significant amount of electronegative gold species (Au δ− ) resulted in higher photoactivity. Also, the samples prepared using the above supports overperform others Au/Pt-TiO 2 composites with the same Au/Pt ratio over different TiO 2 supports (P-25, ST-01, TiO-5, TiO 2 nano-tubes) [143]. In a somewhat parallel contribution, Au/Pd nanoparticles supported on TiO 2 were investigated paying attention to the calcination temperature. Increasing it from 350 to 700 • C deteriorates activity. A modest decrease under UV and quite significant decrease under visible light for phenol photo-degradation can be seen in Figure 9. Catalysts calcined at 350 and 400 • C showed the highest photocatalytic activity for phenol degradation under visible and UV light, respectively. An in-situ EPR study examined the formation of radical species under illumination. This tool found that the O 2− radical species is mainly responsible of the pollutant degradation under all illumination conditions tested. The study was completed with the help of HAADF-STEM (High-angle annular dark-field scanning transmission electron microscopy) and TEM microscopies. Results pointed out that the Pd to Au ratio in the surface layer of Au/Pd nanoparticles decreased from 5:1 to 1:4 with calcination temperature going from 350 to 700 • C, respectively. The overall analysis indicates that increasing calcination temperature caused segregation of metals and gold-enrichment in the outermost region of Au/Pd bimetallic nanoparticles. Optimum photoactivity is connected with the adequate degree of mixing of both metals and the dominant presence of Pd at surface layers ( Figure 9) [144]. Recently, novel Ag-Cu bimetallic alloy NPs decorated β-NaYF4: Yb 3+ , Tm 3+ (NYFT) @TiO2 microrods were prepared by a surfactant-assistant sol-gel method and H2 reduction process. Under nearinfrared (NIR) light irradiation, Ag-Cu alloy supported NYFT exhibited significantly enhanced photocatalytic activity in comparison with other samples (NYFT, NYFT@Ag and NYFT@Cu), and water disinfection involving 100% inactivation of bacteria was achieved within 8 h. The increase in the photoactivity was assigned to the synergistic effect taking place between the up-conversion material and alloy NPs. In the NYFT@Ag-Cu composite, NYFT could convert NIR into UV and visible light. TiO2 absorbed UV emissions and produced electrons and holes. Electrons in the CB of TiO2 could first transfer to Ag then to Cu, which would effectively inhibit recombination of charge carriers and increase their lifetimes [145]. Bimetallic co-catalysts presenting Pt as a major component find application in numerous photocatalytic processes. As an example, Pt-Pd [146] and Pt-Ru [147] cocatalysts supported on nonmetric (ca. 10 nm) anatase were tested in the photoproduction of hydrogen from methanol: water mixtures. For Pt-Pd, optimum activity can be ascribed with the formation of binary alloys having disorder fcc type structure. For Pt-Ru, Pt in a metallic state was located in the proximity of Ru oxide species. Irrespective of the structural situation, the binary systems improve charge separation and overperform the corresponding monometallic system under both UV and sunlight operating conditions. We can also mention a Fe/La/Zn@GO trimetallic nanocomposite, active in the elimination of the phenylhydrazine organic pollutant under sunlight illumination [148].
To end this section, we will briefly mention photo-catalytic oxide systems introduced in polymer matrixes. Titania is the main semiconductor used in this case. The incorporation of nanostructured titanium oxide has been utilized in several polymers such as ethylene vinyl alcohol (EVOH) [149], polypropylene (PP) [150], polycaprolactone (PCL) [151] or polyvinylidene difluoride (PVDF) [152] to generate self-cleaning and self-degrading materials. The analysis of the biocidal properties showed that a good contact between titania can make the whole surface of the composite material biocidal and this provides the grounds for making active surfaces with wide application and at the same time allowing a controlled degradation of the polymer in order to avoid environmental problems [153]. Another important field of application relates to water treatment using membrane materials. Recently, novel Ag-Cu bimetallic alloy NPs decorated β-NaYF 4 : Yb 3+ , Tm 3+ (NYFT) @TiO 2 micro-rods were prepared by a surfactant-assistant sol-gel method and H 2 reduction process. Under near-infrared (NIR) light irradiation, Ag-Cu alloy supported NYFT exhibited significantly enhanced photocatalytic activity in comparison with other samples (NYFT, NYFT@Ag and NYFT@Cu), and water disinfection involving 100% inactivation of bacteria was achieved within 8 h. The increase in the photoactivity was assigned to the synergistic effect taking place between the up-conversion material and alloy NPs. In the NYFT@Ag-Cu composite, NYFT could convert NIR into UV and visible light. TiO 2 absorbed UV emissions and produced electrons and holes. Electrons in the CB of TiO 2 could first transfer to Ag then to Cu, which would effectively inhibit recombination of charge carriers and increase their lifetimes [145]. Bimetallic co-catalysts presenting Pt as a major component find application in numerous photocatalytic processes. As an example, Pt-Pd [146] and Pt-Ru [147] co-catalysts supported on nonmetric (ca. 10 nm) anatase were tested in the photoproduction of hydrogen from methanol: water mixtures. For Pt-Pd, optimum activity can be ascribed with the formation of binary alloys having disorder fcc type structure. For Pt-Ru, Pt in a metallic state was located in the proximity of Ru oxide species. Irrespective of the structural situation, the binary systems improve charge separation and overperform the corresponding monometallic system under both UV and sunlight operating conditions. We can also mention a Fe/La/Zn@GO trimetallic nanocomposite, active in the elimination of the phenylhydrazine organic pollutant under sunlight illumination [148].
To end this section, we will briefly mention photo-catalytic oxide systems introduced in polymer matrixes. Titania is the main semiconductor used in this case. The incorporation of nanostructured titanium oxide has been utilized in several polymers such as ethylene vinyl alcohol (EVOH) [149], polypropylene (PP) [150], polycaprolactone (PCL) [151] or polyvinylidene difluoride (PVDF) [152] to generate self-cleaning and self-degrading materials. The analysis of the biocidal properties showed that a good contact between titania can make the whole surface of the composite material biocidal and this provides the grounds for making active surfaces with wide application and at the same time allowing a controlled degradation of the polymer in order to avoid environmental problems [153]. Another important field of application relates to water treatment using membrane materials. Ultrafiltration membranes using such composite materials are the most commonly reported. Using titania [154,155] or ZnO [156] UV active materials were presented while doping with Nd or graphene oxide (GO) of titania were utilized to trigger the membrane functional properties upon visible light illumination [157]. Finally, other functional composite materials can be exemplified by the ZnO/SiO 2 composite introduced into an ETHOCEL resin as UV light blocker [158].

Conclusions and Outlook into the Future
In this contribution, we survey the work carried out in the photocatalysis field and oriented it to the use of sunlight as the energy source of the photo-chemical process. In this immense field of research, we focus on titania-based materials as the most promising candidate to achieve this goal. Nevertheless, titania is a UV absorber which can be the base of a universal highly efficient system but requires significant engineering to achieve a fruitful use of the full spectrum of the solar light. As the main tools to achieve this goal, we reviewed doped and composite materials as well as the combination between these two approaches.
Doping of the main semiconductors such as titania has been extensively studied. Cation and/or anion doping related to the insertion of metal and non-metal ions in substitutional/interstitial surface and/or bulk positions was used to modify the band gap energy of titania and to create efficient localized electronic states to achieve visible light absorption and activity. A specific case corresponds to up-conversion cations, which allows the utilization of near infrared wavelengths. Similarly, composite materials were utilized to achieve fruitful use of visible and near infrared regions of the solar spectrum. Composite systems using semiconductors with low band gap, or displaying plasmonic or up-conversion capabilities, are highlighted as rather powerful systems. Metal-titania systems were also analyzed in terms of their potential for visible and/or infrared light (in addition to the UV). Ternary systems combining metals, low band gap or up-converters semiconductors and (doped or not) titania are mentioned as potentially the most useful full spectrum photo-catalysts. They require complex preparation procedures and fine tune of the contact between components but would allow future progress of the field. Finally, we briefly reviewed the use of polymers as matrixes to embedded photo-catalytic oxides and generate functional materials with improved capabilities.
Although the full profit of the solar light is an extraordinary challenge, the progress in the field has reached an extraordinary level, mostly relaying in the utilization of the above-mentioned complex materials. The combination of all relevant technologies considering the management of the electronic properties of titania (mainly although not exclusively band gap energy) jointly with the combination of this base material (as well as other base materials such as zinc oxide) within composite systems having (the above-described) specific components to profit from visible and infrared photons seems a clear route to achieve a good photocatalyst that is able to utilize efficiently photons in the complete electromagnetic range of sunlight. Nevertheless, optimization of activity requires the fine tuning of the light-matter interaction and chemical properties of such complex, final materials. This task can be achieved by a careful design and engineering of the structural/electronic properties of each component, the corresponding interfaces among components as well as of the (most) active surfaces to be exposed to the reactive atmosphere. New synthesis methodologies and the advancement in the physico-chemical characterization of the photocatalytic materials would guide out work in achieving this goal.