LaTiO2N/In2O3 photoanodes with improved performance for solar water splitting

LaTiO(2)N photoanodes for solar water splitting were prepared by electrophoretic deposition and demonstrated the best photocurrents ever reported for this material. Further important enhancement of the performance was obtained by the use of a sputtered In(2)O(3) overlayer.     

Time-resolved infrared spectroscopy of K3Ta3B2O12 photocatalysts for water splitting

Electrons photoexcited in K(3)Ta(3)B(2)O(12), an efficient photocatalyst for the water-splitting reaction driven by ultraviolet light, were observed using time-resolved IR absorption spectroscopy with microsecond resolution. When the catalyst was irradiated with 266 nm light pulses, a structureless absorption appeared at 3000-1500 cm(-1). The absorption was assigned to the optical transition of electrons that were band gap-excited and then trapped in mid-gap states. The absorbance decayed with a time delay because of the electron-hole recombination. The rate of recombination in an argon atmosphere was sensitive to the composition of the starting material used in the catalyst preparation. The electron decay was accelerated by exposing the catalyst to water vapor. The degree of acceleration was qualitatively correlated with the H(2) production rate observed during steady-state light irradiation.     

Tungsten doping of Ta3N5-nanotubes for band gap narrowing and enhanced photoelectrochemical water splitting efficiency

Ordered W-doped Ta₂O₅ nanotube arrays were grown by self-organizing electrochemical anodization of TaW alloys with different tungsten concentrations and by a suitable high temperature ammonia treatment, fully converted to W:Ta₃N₅ tubular structures. A main effect found is that W doping can decrease the band gap from 2 eV (bare Ta₃N₅) down to 1.75 eV. Ta₃N₅ nanotubes grown on 0.5 at.% W alloy and modified with Co(OH)_x as co-catalyst show ~ 33% higher photocurrents in photoelectrochemical (PEC) water splitting than pure Ta₃N₅.     

Self-supported hollow Co(OH)2/NiCo sulfide hybrid nanotube arrays as efficient electrocatalysts for overall water splitting

Journal of Solid State Electrochemistry - Developing low-cost and earth-abundant electrocatalysts with high activity for both hydrogen evolution reaction (HER) and oxygen evolution reaction (OER)...     

Ta2O5 nanowires: a novel synthetic method and their solar energy utilization

Single-crystalline uniform Ta(2)O(5) nanowires are prepared by a novel synthetic route. The formation of the nanowires involves an oriented attachment process caused by the reduction of surface energy. The nanowires are successfully applied to photocatalytic H(2) evolution, contaminant degradation, and dye-sensitized solar cells (DSCs). The Ta(2)O(5)-based DSCs reveal a significant photovoltaic response, which has not been reported. As a photocatalyst, the Ta(2)O(5) nanowires possess high H(2) evolution efficiency under Xe lamp irradiation, nearly 27-fold higher than the commercial powders. A better performance of photocatalytic contaminant degradation is also observed. Such improvements are ascribed to better charge transport ability for the single-crystalline wire and a higher potential energy of the conduction band. This new synthetic approach using a water-soluble precursor provides a versatile way to prepare nanostructured metal oxides.     

Direct Z-scheme WO3-x nanowire-bridged TiO2 nanorod arrays for highly efficient photoelectrochemical overall water splitting

All-solid-state Z-scheme photocatalysts for overall water splitting to evolve H2 is a promising strategy for efficient conversion of solar energy.However,most o...     

Preparation of dye-sensitized solar cells using template free TiO2 nanotube arrays for enhanced power conversion

Journal of Sol-Gel Science and Technology - By using the vertically aligned ZnO nanorod arrays (NRAs), TiO2 nanoparticles attached ZnO nanorods (TiO2@ZnO) and TiO2 nanotube arrays (NTAs) were...     

Double-hole-mediated coupling of anionic dopants in perovskite NaNbO3 for efficient solar water splitting

Doping is an effective strategy to improve the photocatalytic performances of semiconductor photocatalyst for water splitting. In this work, we perform extensive hybrid density functional calculations to investigate perovskite NaNbO₃ with anionic monodoping with N, C, P, and S dopants as well as with (N + N), (C + S), and (N + P) codoping pairs. Theoretical results clearly reveal that the band structures of NaNbO₃ can be effectively tailored by introducing double-hole-mediated coupling of anion-anion pairs. Compared with the monodoping cases, the anion-anion codoped NaNbO₃ systems not only have substantially narrowed band gaps, but also can eliminate the unoccupied localized states appearing above the Fermi level, which are disastrous for photocatalysis as they may trap the photogenerated carriers. Optical absorption curves further convince that the codoped NaNbO₃ can effectively harvest visible light. The band edge positions with respect to the redox potentials of water demonstrate that the (N + N) codoped NaNbO₃ are desirable for efficient solar water splitting.     

Vertically aligned mixed V2O5-TiO2 nanotube arrays for supercapacitor applications

Highly ordered mixed V(2)O(5)-TiO(2) nanotubes can be formed by self-organizing anodization of Ti-V alloys with vanadium content of up to 18 at%. In the resulting oxide nanotube arrays, the vanadium is electrochemically switchable leading to a specific capacitance that can reach up to 220 F g(-1) and an energy density of 19.56 Wh kg(-1) with perfect reversibility and long-term stability. Thus these mixed oxide nanotubes may be considered as a promising candidate for supercapacitors.     

Rational design of the nanowall photoelectrode for efficient solar water splitting

The alternate dielectric component is introduced into a nanowall skeleton for the first time. As a photoelectrode, this novel model can optimize the process of photon absorption, charge separation/migration and surface reaction, resulting in superior photoelectrochemical performance.     

Facile electrochemical synthesis of hexagonal Cu2O nanotube arrays and their application

Large-scale and highly oriented single-crystalline hexagonal Cu(2)O nanotube arrays have been successfully synthesized using a two-step solution approach, which involves the electrodeposition of oriented Cu(2)O nanorods and a subsequent dissolution technique along the c axis to form a tubular structure. Herein, NH(4)Cl was found to be an effectual additive, and it can successfully realize the dissolution process of Cu(2)O from nanorods to nanotubes. The dissolution mechanism of Cu(2)O from nanorods to nanotubes was illustrated in detail. These prepared Cu(2)O nanotube arrays were characterized by SEM, EDS, XRD, XPS, and TEM. The photoluminescence (PL) spectrum of Cu(2)O nanotube arrays was also measured, and it shows there is a greater fraction of copper or oxygen vacancies in these prepared Cu(2)O nanotubes. Finally, the applications of Cu(2)O nanotube arrays for gas sensors were investigated in this paper.     

TiO2 nanotube fabrication with highly exposed (001) facets for enhanced conversion efficiency of solar cells

We demonstrate that the use of poly(vinyl pyrrolidone) (PVP) and acetic acid during the synthesis of TiO(2) nanotubes may result in the synthesis of single-crystal-like anatase TiO(2) with a mainly exposed and chemically active (001) facet. An enhancement in the overall conversion efficiency of dye-sensitized solar cells was observed in a photoanode consisting of TiO(2) single-crystal-like anatase exposed (001) facets.     

Synthesis of crystallized TaON and Ta3N5 by nitridation of Ta2O5 thin films grown by pulsed laser deposition

TaON and Ta₃N₅ thin films of different thicknesses were prepared by pulsed laser deposition of tantalum oxide followed by ex situ thermal nitridation under ammonia. The nitridation was carried out in flowing gas in the 600–800 °C temperature range. The dependence of tantalum oxynitride and nitride crystalline phases formation on nitridation reaction parameters was investigated. Structural and microstructural characteristics were investigated by X-ray diffraction (XRD) and scanning electron microscopy (SEM).     

Insights into the efficient charge separation over Nb2O5/2D-C3N4 heterostructure for exceptional visible-light driven H2 evolution

Two-dimensional carbon nitride(2 D-C₃ N₄)nanosheets are promising materials in photocatalytic water splitting,but still suffer from easy agglomeration and fast photogene rated electron-hole pairs recombination.To tackle this issue,herein,a hierarchical Nb₂ O₅/2 D-C₃ N₄ heterostructure is precisely constructed and the built-in electric field between Nb₂O₅ and 2 D-C₃ N₄ can provide the driving force to separate/transfer the charge carriers efficiently.Moreover,the strongly Lewis acidic Nb₂O₅ can adsorb TEOA molecules on its surface at locally high concentrations to facilitate the oxidation reaction kinetics under irradiation,resulting in efficient photogene rated electrons-holes separation and exceptional photocatalytic hydrogen evolution.As expected,the champion Nb₂O₅/2 D-C₃N₄ heterostructure achieves an exceptional H2 evolution rate of 31.6 mmol g^-1 h^-1,which is 213.6 times and 4.3 times higher than that of pristine Nb₂O₅ and2 D-C₃N₄,respectively.Moreover,the champion heterostructure possesses a high apparent quantum efficiency(AQE)of 45.08%atλ=405 nm and superior cycling stability.Furthermore,a possible photocatalytic mechanism of the energy band alignment at the hetero-interface is proposed based on the systematical characterizations accompanied by density functional theory(DFT)calculations.This work paves the way for the precise construction of a high-quality heterostructured photocatalyst with efficient charge separation to boost hydrogen production.     

Translucent thin film Fe2O3 photoanodes for efficient water splitting by sunlight: nanostructure-directing effect of Si-doping

Thin, silicon-doped nanocrystalline alpha-Fe2O3 films have been deposited on F-doped SnO2 substrates by ultrasonic spray pyrolysis and chemical vapor deposition at atmospheric pressure. The photocatalytic activity of these films with regard to photoelectrochemical water oxidation was measured at pH 13.6 under simulated AM 1.5 global sunlight. The photoanodes prepared by USP and APCVD gave 1.17 and 1.45 mA/cm2, respectively, at 1.23 V vs RHE. The morphology of the alpha-Fe2O3 was strongly influenced by the silicon doping, decreasing the feature size of the mesoscopic film. The silicon-doped alpha-Fe2O3 nano-leaflets show a preferred orientation with the (001) basal plane normal to the substrate. The best performing photoanode would yield a solar-to-chemical conversion efficiency of 2.1% in a tandem device using two dye-sensitized solar cells in series.     

Charge Carrier Transport Mechanism in Ta2O5, TaON,and Ta3N5 Studied by Applying Polaron Hopping and Bandlike Models

TaON and Ta₃N₅ are considered promising materials for photocatalytic and photoelectrochemical water splitting. In contrast, their counterpart Ta₂O₅ does not exhibit good photocatalytic performance. This may be explained with the different charge carrier transport mechanisms in these materials, which are not well understood yet. Herein, we investigate the charge transport properties in Ta₂O₅, TaON, and Ta₃N₅ by polaron hopping and bandlike models. First, the polaron binding energies were calculated to evaluate whether the small polaron occurs in these materials. Then we performed calculations to localize the excess carriers as small polarons using a hybrid density functional. We find that the small polaron hopping is the charge transfer mechanism in Ta₂O_5, whereas our calculations indicate that this mechanism may not occur in TaON and Ta₃N₅. We also investigated the bandlike model mechanism by calculating the charge carrier mobility of these materials using the effective mass approximation, but the calculated mobility is not consistent with experimental results. This study is a first step towards understanding charge transport in oxynitrides and nitrides and furthermore establishes a simple rule to determine whether a small polaron occurs in a material.     

Efficient photoelectrodes from anatase TiO2 nanotube arrays decorated with particles/rods/3D microflower rutile crystals for photoelectrochemical water splitting

Journal of Solid State Electrochemistry - Efficient photoanodes are designed of vertically aligned anatase TiO2 nanotube arrays (anatase TNTAs) decorated with different shaped rutile TiO2...     

在光催化还原CO2中具有高催化效率的八面体Cu2O修饰的TiO2纳米管

光催化还原CO2生成烃类燃料是一种可同时解决全球变暖和能源危机问题的最有效途径之一。尽管这方面的研究已经取得了一定的进展,但是整体的光催化转换效率还非常低。因此,需要发展更加高效的催化剂。由于半导体材料禁带宽度与太阳光谱相匹配,人们已经对其进行了广泛研究。其中TiO2因具有无毒、强氧化性以及良好的光学和电学性质等而成为最主要的研究对象。但是对于光催化还原CO2反应来说, TiO2仍存在很多不足,如只能吸收太阳光谱中的紫外光,光生载流子会快速结合,以及光生空穴的强氧化能力等,这些都限制了其光催化还原CO2的效率。采用窄禁带宽度半导体修饰TiO2是解决上述不足的有效途径之一。本文采用简单的电化学方法成功制备了一种由窄禁带半导体Cu2O修饰的TiO2纳米管(TNTs)的复合物,并运用扫描电子显微镜(SEM)、X射线衍射(XRD)以及X射线光电子能谱(XPS)表征了所制备复合物的形貌、化学组成和结晶度。表征结果显示,所制备的TiO2为整齐排列的纳米管阵列结构;复合物中的纳米颗粒为Cu2O;当电化学沉积Cu2O的时间为5 min时,得到的Cu2O纳米颗粒初步呈类八面体结构。随着沉积时间的增加, Cu2O颗粒尺寸增加,具有八面体结构。 XRD和XPS结果表明, TiO2纳米管为锐钛矿,八面体Cu2O纳米颗粒的主要暴露晶面为(111)面。我们还进一步研究了不同量Cu2O纳米颗粒修饰的TiO2纳米管复合物在可见光以及模拟太阳光下光催化还原CO2的能力。在可见光下,由于自身的禁带宽度,纯净的TiO2纳米管没有任何光催化还原CO2的能力;经过Cu2O纳米颗粒的修饰,复合物显现出明显的光催化还原CO2的能力,其中经过30 min Cu2O沉积的TNTs具有最高的光催化效率。在模拟太阳光下,经过15 min Cu2O沉积的TNTs具有最高的光催化效率。在所有光催化还原CO2过程中,主要碳氢产物为甲烷。为了深入地理解该复合体系在还原CO2中的高催化效率,我们对催化剂进行了进一步的表征。紫外-可见漫反射光谱表明, Cu2O八面体纳米颗粒的沉积将TNTs的吸收光谱拓展到了可见光区域,提高了复合物对太阳光的吸收能力。此外,我们还通过测试所制样品的光电流反应、荧光发射光谱以及电化学阻抗谱,研究了催化剂中光生电子和空穴的分离和迁移能力。结果表明,适量的Cu2O沉积提高了复合物对光的吸收能力,增加了光生载流子的数量,从而使更多的光生载流子参与光催化反应。综上,本文首次报道了八面体Cu2O纳米颗粒修饰TNTs复合物的光催化还原CO2的能力。在一定量的Cu2O纳米颗粒修饰下,该复合物在光催化还原CO2生成烃类反应中表现出高效性。经过一系列详细的表征和讨论,我们认为其高效性主要源于三个方面：(1) TNTs的管状结构为反应物的吸附提供了大量的活性位点,同时一维的管状结构更有利于光生载流子的运载,从而提高了电子和空穴的分离;(2) Cu2O纳米颗粒的修饰提高了催化剂对光的吸收,促进催化剂最大程度地利用太阳光;(3) TiO2和Cu2O之间导带以及价带位置的匹配,在减少光生载流子复合的同时也降低了TiO2价带上空穴的氧化能力,从而抑制了CO2还原产物的再氧化过程。