Hydrogen Reduced Rutile Titanium Dioxide Photocatalyst

For TiO 2 photocatalysts, recombination of photoexcited electrons and holes would occur in crystalline defects such as oxygen vacancies, Ti 3+ ions, and surface states. Therefore, it is believed that the density of crystalline defects should be decreased to improve the photocatalytic activity of TiO 2 particles. Contrary to this common knowledge, the introduction of crystalline defects by hydrogen reduction treatment is shown to increase the lifetime of photoexcited electrons in rutile TiO 2 photocatalysts with an increase of n-type electrical conductivity. The photocatalytic activities of H 2 -reduced rutile TiO 2 were higher than those of anatase TiO 2 and mixed-phase TiO 2 . This chapter explains the effect of donor doping on the photocatalytic activity of rutile TiO 2 , the relationship between its physicochemical properties and photocatalytic performances, and the mechanism of the enhanced activity of H 2 -reduced TiO 2 . Particle size dependence on the enhanced activi- ties suggests the formation of a space charge layer in large TiO 2 crystallites. on the photocatalytic activity of rutile TiO 2 . The properties of the H 2 -reduced rutile TiO 2 were characterized using diffuse reflectance UV-vis-NIR spectroscopy, electron spin resonance (ESR) spectroscopy, sheet resistance measurements, and electrochemical Mott-Schottky analysis. The role of oxygen vacancies, Ti 3+ species, and conduction band electrons in the enhancement of photocatalytic and PEC activities of H 2 -reduced TiO 2 is discussed based on the experimental results.


Introduction
For utilization of light energy including solar light, the development of highly active photocatalytic materials is expected. Mainly oxide photocatalysts have been studied so far, but the design guideline did not become clear even in the case of representative TiO 2 . In crystalline type of TiO 2 photocatalysts such as anatase, rutile, and brookite, it is believed that anatase TiO 2 is active based on the studies such as the oxidative degradation of organic compounds, H 2 evolution from water, and photoinduced super hydrophilicity. When anatase TiO 2 is annealed to decrease the density of crystalline defects, the crystal structure is transformed into a thermodynamically stable rutile phase. Generally speaking, the photocatalytic performance of rutile-type TiO 2 is inferior except for the case in specific photocatalyst reactions. The reasons of lower activity are attributed to the smaller BET-specific surface area, the energetically lower conduction band bottom, and the shorter lifetime of the photoexcited carriers, compared to those of anatase TiO 2 .
When oxide photocatalyst absorbs light with energy larger than the bandgap, an electron is excited to the conduction band, and a positive hole generates in the valence band. The lifetime of the photoexcited electron and the hole must be long enough to promote reductive and oxidative reactions on the surface efficiently. However, most of the photoexcited carriers are deactivated by recombination at crystalline defects such as impurities and disorder of the atomic arrangement in the bulk, on the surface, and at the interface. Therefore, highly crystalline particles are considered to show high photocatalytic activity if the band structure and the BET-specific surface area are the same.
The photocatalytic activity of rutile TiO 2 is frequently low compared to that of anatase TiO 2 photocatalyst. However, Maeda recently revealed that a rutile TiO 2 can induce overall water splitting to evolve H 2 and O 2 under UV irradiation [1]. We have also found that photocatalytic activity of rutile TiO 2 was improved by H 2 reduction treatment. The reaction can be written using Kröger-Vink notation ( Table 1). Hydrogen reduction of TiO 2 creates both oxygen vacancy and electrons as shown in Eq. (1). Therefore, this treatment is recognized as a donor doping. The electron is trapped in a Ti 4+ lattice site to form Ti 3+ ions (Eq. (2)). The enhanced activity by introducing lattice defects is against the common knowledge in photocatalyst chemistry: crystalline defects should be decreased.

Doping in oxide photocatalysts
For semiconductor materials in electronic use, the density of electrons and holes is controlled by the doping of impurities into crystalline materials. Doping means incorporation of foreign impurities into the crystalline lattice of the parent semiconductor, and it is significantly different from surface modification. The donor doping implies an introduction of electrons to create an n-type semiconductor. The n-type conductivity is increased by donor doping and decreased by an acceptor doping-introducing hole. The electrons in the conduction band and the trapping site are one of crystalline defects in a wide meaning.
In semiconductor photocatalysts, doping of impurities is used to control the band structures. An impurity level and a subband can be formed in the bandgap by substituting a different ion for an ion constituting a crystal, and it is applied for the development of visible lightresponsive photocatalysts. However, photocatalytic activity under visible-light irradiation has not yet been in practical use because of the low quantum yield. The doped impurities frequently resulted in deactivation of the doped photocatalysts, suggesting that the dopants and the created defects work as a recombination center decreasing the lifetime of photoexcited electrons and holes.

Perovskite oxide photocatalysts
There are many papers reporting the enhancement of photocatalytic activity by doping of cations and anions, although some of the reports lack reproducibility and experimental evidence. For perovskite oxide photocatalysts, some research groups reported that the photocatalytic activity was enhanced by acceptor doping, that is, doping of cations with valence lower than that of the parent cations. It is known that oxygen vacancies are easily formed in perovskite oxides, which resulted in the increase of electron density (Eq. (3)) and the origin of n-type semiconductivity.
The electrons are trapped in shallow midgap states near conduction band bottom and can be easily excited from the donor levels to the conduction band. During photoexcitation, photogenerated holes would recombine with the electrons in addition to the photoexcited electrons. Therefore, a higher accumulation of electrons in n-type oxide would result in lower photocatalytic activity. Actually, this is true for perovskite oxide photocatalysts such as SrTiO 3 and KTaO 3 [2][3][4].
Ishihara et al. reported that the doping of Zr 4+ to KTaO 3 particles was effective for improving the activity for overall water splitting under UV irradiation [2,3]. The photocatalytic activity of nondoped KTaO 3 loaded with a NiO cocatalyst (NiO/KTaO 3 ) was negligible, but the doping of a small amount of tetravalent cations such as Zr 4+ increases the rate of photocatalytic H 2 and O 2 evolution. KTaO 3 was originally an n-type semiconductor, since the electrical conductivity was monotonically increased with decreasing oxygen partial pressure. The doping of acceptors would decrease electron density in KTaO 3 according to Eqs. (4) and (5). The electrical conductivity of KTaO 3 was decreased with an increase of the amount of doped Zr 4+ , which resulted in the enhanced photocatalytic activity.
Takata and Domen also reported that acceptor doping effectively enhanced the photocatalytic activity of cocatalyst-loaded SrTiO 3 particles for overall water splitting [4]. Ga-doped and Nadoped SrTiO 3 exhibited photocatalytic activity higher than that of nondoped SrTiO 3 by about 10 times. Ga 3+ occupies the Ti 4+ site and Na + occupies the Sr 2+ site, which resulted in the decrease of electron concentration (Eqs. (6) and (7)). In contrast, the doping of a higher valence cations (Ta and La) led to the suppressed photocatalytic activity of SrTiO 3 (Eqs. (8) and (9)).
Here, Ta 5+ occupies Ti 4+ site, and La 3+ occupies the Sr 2+ site increasing the electron density of SrTiO 3 . Since the electrons are trapped in Ti 4+ sites to create Ti 3+ species (Eq. (2)), the defect species most responsible for recombination would be Ti 3+ species in n-type perovskite oxide photocatalysts.

TiO 2 photocatalysts
The roles of dopants in TiO 2 photocatalysts are complicated and controversial, since it might depend on the particle size, the crystallinity, the crystalline phase, and reaction conditions. Generally speaking, impurities and crystalline defects work as recombination centers. However, there are some reports pointing that donor doping enhanced the photocatalytic activity of Pt-loaded TiO 2 [5,6]. This trend for Pt/TiO 2 photocatalysts is opposite to the case of perovskite oxides, which is activated by acceptor doping.
Karakitsou and Verykios reported the effect of aliovalent cation doping to the TiO 2 matrix on the photocatalytic activity of Pt/TiO 2 for H 2 evolution [5]. Since the doped TiO 2 was prepared at 900 C, the crystalline structure was rutile phase and the particle size was large (BET-specific surface area,~1 m 2 g À1 ). In contrast to the case of perovskite oxides mentioned above, the doping of cations with valence higher than Ti 4+ (W 6+ , Ta 5+ , and Nb 5+ ) enhanced the photocatalytic activity, while the opposite was observed for acceptor doping (In 3+ , Zn 2+ , and Li + ). The measurement of electrical conductivity revealed that the cation doping changed the bulk electronic structure [7]. The authors concluded that n-type conductivity correlates with the enhanced photocatalytic activity of Pt/TiO 2 with rutile form.
Ying et al. investigated the role of particle size in cation-doped TiO 2 nanoparticles with anatase crystalline structure [6]. For TiO 2 nanocrystals with an average diameter less than 11 nm, the doping of Fe 3+ enhanced the photocatalytic activity for CHCl 3 degradation. The optimal concentration of Fe 3+ dopants decreased with increasing TiO 2 particle size, suggesting that the role of Fe 3+ species is the inhibition of surface recombination. The Fe 3+ doping might work less effectively for large TiO 2 particles, since the dominant recombination process is bulk recombination rather than surface recombination. The photocatalytic activity of TiO 2 with large particle size was increased by Nb 5+ doping in a combination with Pt loading, while the activity was decreased by sole Nb 5+ doping.

Deactivation of TiO 2 photocatalysts at high temperature
Improving crystallinity by annealing can enhance the photocatalytic activity of TiO 2 by decreasing defects that act as recombination centers. However, high temperature calcination frequently decreased photocatalytic activity. This deactivation is commonly attributed to a change of the crystal structure from anatase to rutile and a decrease in BET-specific surface area because of crystal growth. Both crystallinity and specific surface area, which are related to particle size, are changed by high temperature calcination. Therefore, it is difficult to characterize the effect of annealing except for the effects by crystal growth.
We investigated the effect of high temperature calcination on the photocatalytic activity of rutile TiO 2 with a small BET-specific surface area,~2.3 m 2 g À1 , to diminish the change in the crystalline phase and surface area by crystal growth [8]. Photocatalytic activity toward H 2 evolution was examined using an aqueous ethanol solution, with in-situ photodeposited Pt nanoparticles, under UV irradiation. Figure 1 shows that the rate of photocatalytic H 2 evolution was significantly decreased by calcination in air at temperatures higher than 500 C, although the BET-specific surface area showed a little change. These results indicated that the deactivation of rutile TiO 2 particles at high temperature calcination could not be attributed to the phase transition and the decreased surface area.
Then, the behavior of photoexcited electrons was examined using transient IR spectroscopy to probe the dynamics of photoexcited electrons [8]. Changes in IR absorption were recorded after the pump irradiation of 355-nm laser pulse in the presence of methanol. Owing to low signal levels under vacuum, methanol was added as an electron donor. Figure 2 shows the millisecond-scale decay of the photoinduced IR absorption observed for calcined rutile samples. Since the photogenerated holes react with methanol within a millisecond, the decay of the signal attributed to photoexcited electrons is very slow. The signal magnitude decreased as calcination temperature of the sample increased, suggesting the more recombination of photoexcited carriers. The rutile TiO 2 particles calcined at high temperature showed the less density of long-lived photoexcited electrons, which resulted in the low photocatalytic activity. The reason for the deactivation at high temperature calcination is attributed to fast charge carrier recombination.

Photocatalytic activity of reduced TiO 2
TiO 2 is often considered as a nonstoichiometric oxygen-deficient compound. According to Eq. (3), a small amount of electrons would be naturally doped. However, the n-type conductivity may be decreased by calcination in air at high temperature owing to the strong oxidation. To confirm the effect of electron density on the fast recombination observed in deactivated  TiO 2 , we performed H 2 reduction treatment to the rutile TiO 2 particles calcined at 1100 C [8].
The TiO 2 samples were reduced by H 2 at 500 or 700 C, increasing both the density of longlived charge carriers and photocatalytic activity ( Figure 3). These results suggest that the density of oxygen vacancies and/or electrons is an important factor determining the photocatalytic activity.
H 2 reduction treatment has received extensive attention for improving the photocatalytic activity of anatase TiO 2 nanostructures since the recent report of the visible-light sensitivity of "hydrogenated black TiO 2 " with defect disorders [9]. H 2 reduction treatment has also been reported to improve the PEC activity of TiO 2 nanowire arrays [10]. The H 2 treatment creates a high density of oxygen vacancies and electrons as shown in Eq. (1). We investigated the effects of H 2 treatment temperature on the photocatalytic activity of rutile TiO 2 particles to discuss the role of oxygen vacancies, Ti 3+ ions, and conduction band electrons [11]. The photocatalytic activity was examined using an O 2 evolution from an aqueous solution of 50 mmol L À1 AgNO 3 as a sacrificial electron acceptor (4Ag + + 2H 2 O ! 4Ag 0 + O 2 + 4H + ). Calcination above 900 C decreased the photocatalytic activity of rutile TiO 2 particles probably owing to strong oxidation, but its initial activity was restored by H 2 treatment at above 500 C. The photocatalytic activity of reduced TiO 2 was hardly changed after recalcination in air at 300 C, but significantly decreased after recalcination at 500 C.

ESR and UV-vis-NIR spectroscopy
Electron spin resonance (ESR) is active for paramagnetic species such as Ti 3+ ions (electron trapped in titanium lattice site) and O •À radicals (hole trapped in oxygen lattice site). Figure 4A shows ESR spectra of the H 2 -reduced TiO 2 samples [11]. The TiO 2 calcined at 1100 C exhibited signals with g = 2.061 and 2.045. Kumar et al. have reported radical formation (g 1 = 2.026, g 2 = 2.017, and g 3 = 2.008) on rutile TiO 2 by calcination at 750 C and assigned the signals to trapped holes on the surface (Ti 4+ O 2À Ti 4+ O •À radicals) [12]. It has been reported that strong oxidation of TiO 2 facilitates the transformation of n-type oxygen-deficient TiO 2Àx to p-type metal-deficient Ti 1Ày O 2 [13]. The high temperature calcination of TiO 2 may be considered The signals attributable to O •À radicals (trapped hole) disappeared after H 2 treatment at 400 C, indicating that strongly oxidized Ti 1Ày O 2 was reduced to neutral TiO 2 by the mild H 2 treatment. The ESR spectrum of TiO 2 reduced at 500 C exhibited a sharp signal at g = 2.002 assigned to electrons trapped in oxygen vacancies and an intense signal at g = 1.974 assigned to Ti 3+ ions (electron trapped in Ti lattice site) in rutile. This indicates that H 2 treatment at 500 C further reduced the TiO 2 to oxygen-deficient TiO 2Àx . The signal at g = 1.974 was significantly broadened when the H 2 treatment temperature was increased to 700 C, indicating the high density of Ti 3+ ions. The TiO 2 reduced at 700 C was assumed to be deeply doped n-type TiO 2 .
The color of the TiO 2 samples changed from white to a pale ash color after H 2 reduction treatment [11]. Figure 4B shows diffuse reflectance UV-vis-NIR spectra of the TiO 2 samples. The onset of intense photoabsorption originating from interband transitions was located at ca. 415 nm corresponding to the bandgap of rutile, 3.0 eV. The spectrum of TiO 2 reduced at 500 and 700 C exhibited a broad absorption located in the visible and NIR region, which can be assigned to the transition of electrons in shallow traps and the conduction band. From the NIR absorption, the density of electrons in the TiO 2 reduced at 500 C was higher than that in the TiO 2 reduced at 700 C. Therefore, it is concluded that H 2 reduction at higher temperature increased the density of electrons in the conduction band. Figure 5 shows X-ray photoelectron spectra of the strongly oxidized TiO 2 and reduced TiO 2 [11]. There was no significant change in the Ti 2p spectra. The binding energy of 458.6 eV for Ti 2p 3/2 was similar to the literature value for Ti 4+ in TiO 2 . This indicates that the amount of Ti 3+ ions on the surface of reduced TiO 2 was too small to analyze by XPS. In contrast, there was a significant difference observed in the O 1s spectra. The peak at 529.8 eV was assigned to lattice oxygen of TiO 2 , and the shoulder peak at 531.5-532.0 eV was assigned to surface hydroxyl groups. Unexpectedly, the area assigned to the hydroxyl group was higher in intensity for reduced TiO 2 than that of oxidized TiO 2 . This is because the oxygen vacancies at the top surface became filled by reaction with H 2 O in the air. It is reported that oxygen vacancies induce dissociation of water molecules and form two hydroxyl groups via H + transfer to a neighboring lattice oxygen according to Eq. (11) [14]. Therefore, oxygen vacancies are not considered to be present on the surface of reduced TiO 2 under ambient conditions. This suggests that oxygen vacancies are not a catalytic site in reduced TiO 2 photocatalysts.

PEC and electrochemical properties
Thermally oxidized TiO 2 films were prepared by a simple calcination of a Ti sheet at 900 C [11]. Figure 6A shows PEC properties evaluated in dilute sulfuric acid (0.1 mol L À1 H 2 SO 4 , pH = 1) under UV irradiation (wavelength >330 nm). The thermally oxidized TiO 2 film was inactive for  PEC water oxidation. The photocurrent was also negligible for the TiO 2 films treated with H 2 at 400 C. However, anodic photocurrent was observed at applied potentials larger than +0.1 V versus Ag-AgCl after H 2 treatment at higher temperature, suggesting the formation of longlived holes in the reduced TiO 2 films. Figure 6B shows the relationship between sheet resistance and donor density of the thermally oxidized TiO 2 films after H 2 treatment [11]. The sheet resistance was measured using a fourpoint probe. The donor densities were evaluated by Mott-Schottky analysis of the capacitance of the space charge layer. The Mott-Schottky plots of the TiO 2 films showed a positive slope of n-type conductivity. The resistance of the thermally oxidized TiO 2 films was high owing to their low donor density. H 2 treatment at above 450 C greatly reduced the sheet resistance and increased the donor density. H 2 treatment at 600 C increased the donor density by 2-3 orders of magnitude. The enhanced PEC and photocatalytic properties are because of the increase of n-type conductivity by H 2 treatment.

Phase junction between anatase and rutile
A mixture of anatase and rutile phases has been reported to be more active than either pure phase alone. Incidentally, the highly efficient commercial photocatalyst Degussa (Evonik) P25 consists of mainly the anatase phase (~80%) with a reasonable amount of rutile (~15%). Because a synergetic effect between anatase and rutile phases is often not observed when separately synthesized powders are simply mixed together, close contact of the phases with each other is expected to be necessary. The high activity of the mixture of phases has been attributed to the separation of photoexcited charge carriers between the two phases. Anatase is considered to be an active component in mixed-phase TiO 2 , while rutile is considered to act as an electron sink because of the lower conduction band energy than that of anatase. In contrast, an ESR study revealed that photoexcited electron transfer occurred from the conduction band of rutile to that of anatase in mixed-phase P25 [15]. This would be because the trapping sites of anatase lie below the energy level of the conduction band of the rutile phase. However, in attempts to explain electron transfer from the conduction band of rutile to that of anatase, it is reported that the conduction band of rutile lies~0.4 eV above that of anatase based on calculation and X-ray photoelectron spectroscopy studies [16]. In this way, there is controversy over the alignment of the conduction band minima of rutile and anatase phases of TiO 2 , experimental results suggest that the photoexcited electrons of rutile are less active than those of anatase. It is reputed that pure rutile is less active for photocatalytic H 2 evolution from water than pure anatase and mixed-phase TiO 2 .

Reduced TiO 2 with pure rutile phase
As mentioned, TiO 2 P25 is a well-known commercial material with high photocatalytic activity. The mixture of anatase and rutile phases in P25 is reportedly more active than the individual polymorphs of TiO 2 . Contrary to this viewpoint, we demonstrated that H 2 -reduced rutile TiO 2 is much more active than mixed-phase P25 for photocatalytic H 2 evolution from aqueous ethanol solution [17,18]. To confirm that the anatase phase does not work as an active component, we investigated H 2 reduction treatment of pure single-phase rutile particles [17]. P25 was first calcined in air at 900 C to induce complete phase transition from anatase to rutile, and then the pure rutile phase was reduced by H 2 at 700 C ( Figure 7A). The photocatalytic H 2 evolution rate was enhanced to 344 µmol h À1 after H 2 reduction treatment at 700 C ( Figure 7B).
Highly efficient rutile photocatalyst is easily fabricated from P25 by H 2 reduction treatment at 700 C for 2 h [18]. The H 2 -reduced rutile TiO 2 outperforms anatase-rich TiO 2 because of the wider absorption range caused by its bandgap of rutile (3.0 eV) smaller than that of anatase (3.2 eV). The apparent quantum yield of H 2 -reduced rutile TiO 2 was estimated to be 46% for photocatalytic H 2 evolution under 390-nm irradiation, which was 3.3 times higher than that of mixed-phase P25.
6. Effect of particle size 6.1. Reduced TiO 2 with large particle size Crystalline size is one of factors affecting the lifetime of photogenerated charge carriers in oxide photocatalysts. For photocatalytic O 2 evolution by water oxidation, anatase TiO 2 nanoparticles exhibit poor activity, while larger rutile particles are more efficient. Large WO 3 particles with low surface area-to-volume ratios are suited to providing long-lived photogenerated holes for water oxidation [19]. This is because slow bulk recombination is the dominant process in larger particles, rather than fast surface recombination.
Controlling the crystalline size of H 2 -reduced TiO 2 is expected to improve the photocatalytic activity for O 2 evolution by water oxidation. The crystalline size and electron density of rutile TiO 2 particles (BET-specific surface are 17 m 2 g À1 ) was controlled by high-temperature calcination and subsequent H 2 reduction [20]. The photocatalytic activity of TiO 2 for water oxidation was significantly improved by H 2 reduction at 700 C, after calcination at 1100 C ( Figure 8). The effect of H 2 reduction treatment was obtained only if the rutile particle was previously calcined at temperatures higher than 1000 C. The improved activity was probably due to a combination of the increased crystalline size and the increased electron concentration. The H 2 -reduced TiO 2 exhibited high apparent quantum yield for O 2 evolution, 41% under irradiation at 365 nm.
Photocatalytic efficiencies per unit of BET-specific surface area were calculated to consider surface reactivities [20]. The surface reactivity for water oxidation, defined as the O 2 evolution rate per unit of surface area, was significantly improved by H 2 treatment when the samples were previously calcined at >1000 C. It was found that H 2 treatment also improved the surface reactivities for photocatalytic H 2 evolution and photocatalytic CO 2 evolution (oxidative decomposition of acetic acid). The H 2 treatment effectively improved the surface reactivity of TiO 2 calcined at high temperature, without dependence on a particular photocatalytic reaction. Thus, the improvement was not due to the surface modification such as a creation of catalytic active sites, but due to the change of electronic properties.
6.2. Mechanism of the enhanced activity Figure 9 shows a schematic illustration of the Fermi level in reduced TiO 2 . An increase in the electron concentration of n-type semiconductors results in an improvement of the electrical conductivity and an upward shift of the Fermi level toward the conduction band edge [21]. When n-type TiO 2 contacts with water, space charge layer forms at the interface by electron transfer from conduction band, with a simultaneous potential drop inside TiO 2 ( Figure 10). This is so-called band bending. The higher Fermi level of n-type TiO 2 resulted in the increase of the surface barrier of Schottky type and the electric field in space charge layer. The intrinsic electric field in the space charge layer separates photoexcited electrons and holes, preventing their recombination. This facilitates the transfer of holes from the valence band to the reactants. The width of space charge layer (W) is determined by the donor density (N D ) and the potential drop in the layer (Δϕ 0 ) according to Eq. (12) [21].
where ε 0 is the permittivity of vacuum, ε is the dielectric constant of semiconductor, and e is electronic charge. As the electron concentration increases, the space charge layer narrows. Thus, there exist an optimum electron concentration and an optimum particle size depending on this concentration. For example, W can be calculated to be 220 nm at N D = 10 17 cm À3 , assuming Δϕ 0 = 500 mV, and taking ε for rutile to be 86. The radius of photocatalyst particle should be larger than this thickness to obtain a band bending. The calcination temperature dependence observed in Figure 8 can be explained in terms of the relation between the particle size and the thickness of space charge layer. High-temperature calcination would be necessary to increase the TiO 2 particle size to an optimum value, 500 nm-1 µm, to form space charge  layer thickness. The formation of space charge layer is suggested to be involved in the activation mechanism of H 2 -reduced rutile TiO 2 with large particle size.

Conclusion
H 2 reduction treatment enhanced the photocatalytic activity and PEC properties of rutile TiO 2 with large particle size. One of the most important factors deciding the photocatalytic activity of reduced TiO 2 is the density of electrons in shallow traps and conduction band, rather than the density of oxygen vacancies. H 2 treatment at 500 C created Ti 3+ ions (trapped electrons), while treatment at 700 C increased the density of conduction electrons, resulting in an improvement of the electrical conductivity of the TiO 2 by 2-3 orders of magnitude. The enhanced activity of the reduced TiO 2 suggests that n-type conductivity governed by electron density plays an important role in suppressing fast recombination by facilitating charge transport. The suppression of recombination in the reduced TiO 2 was caused by not only the high electrical conductivity but also the band bending in space charge layer. The built-in electric field facilitates charge separation and charge transfer. Thus, the surface reactivities of reduced TiO 2 with large particle size were enhanced without dependence on reactions. It was demonstrated that H 2 -reduced rutile TiO 2 exhibited photocatalytic activity higher than that of anatase TiO 2 and mixed-phase TiO 2 .