TiO2 Lattice Research Articles

Functionally Graded Oxide Scale on (Hf,Zr,Ti)B2 Coating with Exceptional Ablation Resistance Induced by Unique Ti Dissolving.

Multicomponent Ti-containing ultra-high temperature ceramics (UHTCs) have emerged as more promising ablation-resistant materials than typical UHTCs for applications above 2000 °C. However, the underlying mechanism of Ti improving the ablation performance is still obscure. Here, (Hf,Zr,Ti)B2 coatings are fabricated by supersonic atmospheric plasma spraying, and the effects of Ti content on the ablation performance under an oxyacetylene flame are investigated. The (Hf0.45Zr0.45Ti0.10)B2 coating shows superior ablation resistance and cycling reliability at ≈2200°C. A functionally graded oxide scale comprising an outer dense layer and an underlying fine granular layer formed. The former is a better oxygen barrier owing to fewer cracks and the latter has high strain tolerance due to finer grain size. The uniform dissolving of ≈4 mol% Ti in the inner layer results in grain refinement via sluggish diffusion and thus stress release. For the outer layer, Ti segregation at the nanoscale leads to a metastable cubic (Hf,Zr,Ti)O2 and local severe lattice distortion, inhibiting the propagation of cracks. Ti ions' unique dissolving in the oxide scale enables a strong oxygen diffusion barrier with high strain tolerance, which is responsible for superior performance. This study provides new insights into the ablation behavior of Ti-containing multicomponent UHTCs.

Integrating Interactive Ir Atoms into Titanium Oxide Lattice for Proton Exchange Membrane Electrolysis.

Iridium (Ir)-based oxide is the state-of-the-art electrocatalyst for acidic water oxidation, yet it is restricted to a few Ir-O octahedral packing modes with limited structural flexibility. Herein, the geometric structure diversification of Ir is achieved by integrating spatially correlated Ir atoms into the surface lattice of TiO2 and its booting effect on oxygen evolution reaction (OER) is investigated. Notably, the resultant i-Ir/TiO2 catalyst exhibits much higher electrocatalytic activity, with an overpotential of 240 mV at 10 mA cm-2 and excellent stability of 315 h at 100 mA cm-2 in acidic electrolyte. Both experimental and theoretical findings reveal that flexible Ir─O─Ir coordination with varied geometric structure plays a crucial role in enhancing OER activity, which optimize the intermediate adsorption by adjusting the d-band center of active Ir sites. Operando characterizations demonstrate that the interactive Ir─O─Ir units can suppress over-oxidation of Ir, effectively widening the stable region of Ir species during the catalytic process. The proton exchange membrane (PEM) electrolyzer, equipped with i-Ir/TiO2 as an anode, gives a low driving voltage of 1.63 V at 2 A cm-2 and maintains stable performance for over 440 h. This work presents a general strategy to eliminate the inherent geometric limitations of IrOx species, thereby inspiring further development of advanced catalyst designs.

Catalytic Advancements in NH3 Selective Catalytic Oxidation: The Impact of Cu-Induced Lattice Distortion in TiO2 Crystal Structure.

A series of x Cu-TiO2 obtained from the sol-gel method were tested for NH3 selective catalytic oxidation (NH3-SCO). Its performance was higher than that of supported Cu/TiO2-Im and solvent-free Cu/TiO2-SF. The catalyst exhibits better water resistance at 300 °C. XRD, Raman, and H2-TPR proved that the crystal lattice of TiO2 was deformed by Cu doping, which increased the specific surface area of the catalyst. The dispersion of the Cu component is further enhanced. The enhancement of redox potential was the key to improving catalytic activity. The NH3-TPD results prove that more acidic sites promote more active NH3 species being adsorbed and dissociated on the catalyst surface. The in-situ DRIFTs results certify that the NH3 species adsorbed on the Lewis acid sites were easier to consume than those on the Brønsted acid sites. The DFT theoretical calculation demonstrates that the doped Cu promotes the TiO2 conduction band to move closer to the Fermi level and enhances the redox performance of the catalyst. The results suggest that the Cu-TiO2 catalyst was a potential catalyst under actual working conditions, which would provide a technological reserve for the development and diffusion of ammonia slip for both mobile and fixed sources.

Favoring the Originally Unfavored Oxygen for Enhancing Nitrogen-to-Nitrate Electroconversion

Nitrate (NO3 −), one of the most crucial forms of reactive nitrogen, is widely used in industry and agriculture. Currently, NO3 − is manufactured predominantly via a two-step procedure, including the Haber–Bosch process for ammonia synthesis and the Ostwald process for ammonia oxidation. However,both techniques require high-pressure and high-temperature reaction conditions (Haber–Bosch reaction at 150-200 bar and 400-500 ℃; Ostwald reaction at 4-10 bar and 800-1000 ℃), which consumes 1-2% of world energy and releases 1-2% of CO2. In addition, due to the complexity of the Ostwald and Haber-Bosch processes, it is only economical at large scales, leading to centralized production, which situation is poorly matched with the distributed nature of HNO3 utilization. Therefore, bypassing the ammonia route and developing a direct and sustainable approach for NO3 − synthesis is highly desirable.Electrochemical synthesis of chemicals has been regarded as an attractive alternative to traditional thermochemical methods since electric potential can replace high temperature and pressure in electrochemical reactions as the thermodynamic driving force. Therefore, direct electrochemical oxidation of molecular nitrogen appears to be a potential approach for NO3 − synthesis,which could be sustainable, modular and easily integrated with intermittent renewable electricity. However, due to the lack of natural catalysts as a reference, the nitrogen oxidation reaction (NOR) still needs to be explored despite its enormous practical value as a replacement for the fossil fuel-driven two-step nitrate preparation approach. To date, only a few works have reported nitrate's electrosynthesis from nitrogen, and the proposed electrocatalysts can only achieve limited NOR activity and selectively due to the complex reaction networks which involve multi-electron transfers, multi-bond breaking and formation steps. In addition, oxidation evolution reaction (OER) as a competitive reaction further limits the selectivity toward nitrate synthesis.One major challenge in improving electrochemical NOR is that its reaction pathways and reactivity are highly sensitive to the catalyst-active-site identity and the non-catalyst components at the electrode/electrolyte interface, such as the local reaction environment. Even minor changes at the catalyst-reaction environment interface can significantly impact the overall catalytic performance.However, the previous works generally regarded the catalyst and reaction environment as two independent systems despite their dynamic interaction throughout the electrochemical reaction20. For example, most works improve NOR performance only by designing the morphologies, chemical states, and compositions of the catalysts. To date, a comprehensive design on the interplays between the above catalyst–reaction environment and the NOR performance is absent, which motivates us to employ a synergistic strategy to regulate both catalyst and reaction environment to achieve the overall optimization of the electrocatalytic interface from the microstructure to the macrosystem, thereby achieving the improvement of NOR performance.Here, we propose that the intrinsic property of the catalyst structure and its reaction environment can be considered as gradient interfaces, ranging from microstructure to macroenvironment, to achieve the effect of one plus one greater than two in terms of NOR performance. Specifically, we synthesized Ru nanoclusters confined within the lattice of TiO2 (RuNC@TiO2) as a microstructural interface and created a macro-interface environment through which we synergistically achieved exceptional NOR performance. The introduced TiO2, an oxophilic species with strong OHad adsorption capability, inhibits OER on Ru active sites by competitively adsorbing OHad between Ru and TiO2. Consequently, the OER on Ru clusters is effectively suppressed due to the preferential adsorption of OHad on TiO2. Importantly, we propose leveraging a macro-interface environment by utilizing the previously considered unfavored oxygen from OER, successfully enhancing the NOR via Le Chatelier's principle. As an experimental demonstration, the as-prepared RuNC@TiO2 delivered a record-high nitrate yield rate of 26.80 μg h-1 cm-2 (20.54 mol h-1 gRu -1) and a Faradaic efficiency of 35.52 % under simulated conditions with high-concentration oxygen (8 atm air). In addition, an increasing nitrate yield rate and Faradaic efficiency (38.87%) after a continuous 20-hour electrochemical process was found due to the increasing oxygen concentration in the reaction environment caused by the OER. Figure 1

In Situ NMR Study on Hydrogen Incorporation in Electrochromic Oxides WO3 and TiO2

Transition metal oxides such as WO3 and TiO2 are well-known electrochromic materials showing color change by ion insertion or extraction [1, 2]. Owing to their electrochromic properties, these oxides are widely investigated as a switchable glazing for a variety of energy-saving and optical switching applications. Recently, application of electrochromic oxides to hydrogen monitoring devices has been proposed to detect hydrogens in steel materials which cause hydrogen embrittlement [3]. In these devises, electrochromic oxides are deposited on steel materials and detect the incorporated hydrogens by their color change. For this application, elucidation of fundamental hydrogen incorporation behavior is necessary to determine suitable materials for hydrogen detection. This study focuses on hydrogen incorporation in well-known electrochromic materials, WO3 and TiO2. Their hydrogen incorporation behavior is analyzed by in situ nuclear magnetic resonance (NMR) spectroscopy. NMR spectroscopy is a powerful tool to observe difference in chemical environment around probing nuclei. Among NMR active nuclei, 1H shows the highest sensitivity and even a small amount of hydrogen species in oxides can be detected. Furthermore, 1H NMR experiments are carried out in situ under H2 atmosphere to clarify the hydrogen incorporation behavior. The purpose of this study is to clarify the hydrogen incorporation behavior of WO3 and TiO2 by in situ 1H NMR and evaluate capability for hydrogen monitoring applications.Powders of WO3 and TiO2 were coated with Pd to ensure hydrogen incorporation in H2 atmosphere and pressed into f4 mm pellets. In situ 1H NMR experiments were carried out using a NMR probe and atmosphere control system specially designed for in situ measurements [4]. 1H NMR spectra were collected from room temperature to 300°C under H2 flow atmosphere. In the 1H NMR spectra of WO3, peaks from adsorbed hydrogen (H) is observed at temperature 100°C and below. This peak is originated from adsorbed H on the Pd coating because this peak is also observed in 1H spectra of Pd powder in H2 atmosphere. At 150°C, a new peak is observed and assigned to H in the WO3 lattice (H x WO3). This peak is separated into two peaks by increasing temperature. These results indicate hydrogen incorporation into WO3 occurs at temperature above 100°C and two chemically distinct H are exist in the WO3 lattice at higher temperature. At lowering temperature, two peaks from H x WO3 become one broad peak and a peak from adsorbed H appears again at 100°C. When atmosphere is changed from H2 flow to vacuum, the adsorbed H peak disappears and only the H x WO3 peak remains indicating incorporated H is stable at room temperature under vacuum. The same procedure is carried out for TiO2. Unlike WO3, a peak assigned to H in the TiO2 lattice is observed even at room temperature under H2 flow. By increasing temperature, the intensity of this peak decreases indicating desorption of H. This temperature dependence is almost reversible at lowering temperature. The peak from H in TiO2 almost disappears when atmosphere is changed from H2 flow to vacuum indicating H in TiO2 is unstable and removed from the lattice by evacuating. The present study reveals quite different hydrogen incorporation behavior of WO3 and TiO2. Using hydrogen incorporation behavior of WO3 as a benchmark, TiO2 is expected to show faster incorporation of hydrogen but the stability of hydrogen in the lattice can be a drawback for hydrogen detecting applications.

Breaking new grounds: Solid-state synthesis of TiO2–La2O3–CuO nanocomposites for degrading brilliant green dye under visible light

Environmental pollution, particularly from industrial dyes and chemicals, poses a significant threat to ecosystems and human health. Traditional pollution mitigation methods are often inefficient and costly. Photocatalysis has emerged as a promising solution for degrading pollutants using light energy. Titanium dioxide (TiO2) is a widely studied photocatalyst due to its stability, non-toxicity, and strong oxidative power. However, its efficiency is limited by a wide bandgap, restricting absorption to the UV region, and rapid electron-hole recombination. To address these limitations, doping TiO2 with materials (La2O3 and CuO) can enhance its photocatalytic activity under visible light. This study investigates the enhancement of TiO2 nanocomposites by incorporating La2O3 and CuO. X-ray diffraction (XRD) revealed that the nanocomposites retained the TiO2 anatase and rutile phases with their improved crystallinity. Scanning electron microscopy (SEM) displayed spherical nanoparticles forming agglomerates, typically due to high surface energy. Energy-dispersive X-ray spectroscopy (EDS) and X-ray photoelectron spectroscopy (XPS) confirmed the presence of La and Cu in the TiO2 matrix. Fourier-transform infrared (FTIR) spectroscopy identified characteristic vibrational modes of Ti–O, La–O, and Cu–O bonds, suggesting strong interactions between dopants and TiO2 lattice. Ultraviolet–visible (UV–vis) spectroscopy showed a red shift in absorption spectra with La2O3 and CuO addition, reducing the bandgap energy from 3.23 eV (pure TiO2) to 2.27 eV for the TiO2–0.1La2O3–0.2CuO composite. Photoluminescence (PL) spectroscopy indicated improved charge separation and reduced electron-hole recombination rates in the synthesized nanocomposites. Photocatalytic performance was evaluated by degrading brilliant green (BG) dye under visible light. The TiO2–0.1La2O3–0.2CuO (TLC0.2) nanocomposite achieved the highest dye degradation of over 95% after 204 min under optimal conditions (Co = 17 mg/L and 1 g/L). Adding the inorganic agent Na2SO4 to this process significantly enhanced the photocatalytic activity, increasing degradation from 56% to 95% after 180 min of visible light irradiation. TLC0.2 exhibited a high stability of dye degradation efficiency after six consecutive photocatalysis cycles. La2O3 and CuO doping significantly enhance TiO2 nanocomposites' crystalline structure, morphology, optical property, and photocatalytic efficiency. TLC0.2 has a potential use for environmental remediation and solar energy conversion.

Zn-Modified TiO2 Thin-Films for Real-Time Formaldehyde Sensing at Room Temperature

Abstract This study explores the fabrication and application of zinc-modified titanium dioxide (Zn-TiO2) thin-films for real-time recognition of volatile organic compounds (VOCs), with a particular emphasis on formaldehyde (HCHO) sensing at room temperature. The Zn-TiO2 thin-films were produced using an economical spray-pyrolysis method. Structural, morphological, and optical characterizations confirmed the successful integration of zinc with varied Wt.% (0, 2, 4, and 6) into the TiO2 lattice. The real-time monitoring capabilities of the sensors were assessed against a range of VOCs, highlighting its specificity for formaldehyde detection amidst diverse environmental constituents. The fabricated thin film sensors with zinc dopant were optimized to enhance the sensor's performance. 4 Wt.% Zn-TiO2 demonstrated excellent sensitivity to formaldehyde vapor at ambient conditions, showcasing a rapid and selective response. The underlying sensing mechanism was explored, emphasizing the role of zinc doping in tailoring the material's surface properties and facilitating enhanced adsorption of formaldehyde molecules. The study underscores the potential of Zn-modified TiO2 thin films as a reliable and efficient platform for real-time VOC monitoring, with a specific focus on HCHO sensing at room-temperature. The sensor shows remarkable stability and repeatability, making it a promising candidate for continuous monitoring applications.

Modulating NH3 oxidation and inhibiting sulfate deposition to improve NH3-SCR denitration performance by controlling Mn/Nb ratio over MnaNbTi2Ox (a = 0.6-0.9) catalysts

The MnaNbTi2Ox (a = 0.6–0.9) catalysts for NH3 selective catalytic reduction denitration were prepared using the co-precipitation method. Among them, Mn0.7NbTi2Ox exhibits well low-temperature catalytic performance, wide activity temperature range (180–480 ℃), and worthy resistance to SO2 even with H2O. XRD was used to investigate the structure of MnaNbTi2Ox, in which Mn and Nb oxides highly dispersed in the MnaNbTi2Ox catalysts and Nb can dope into the crystal lattice of TiO2. XRF and XPS results show Nb can affect the transfer of electrons to Mn4+, and changing the Mn/Nb ratio can regulate the Mn4+ content on the MnaNbTi2Ox catalysts. H2-TPR, NH3 and NO oxidation results verify that Nb inhibits the oxidation capacity of MnaNbTi2Ox, and altering the Mn/Nb ratio can get appropriate oxidation property, which facilitates low-temperature NH3 activation and limit non-selective oxidation for NH3. In-situ DRIFTS results show Nb-OH bonds can provide new Brønsted acid sites, and both Lewis and Brønsted acid sites are active. Furthermore, Nb addition prevents sulphate deposition on the catalyst. The effect of Mn/Nb on catalytic performance, N2O formation and inhibition, SO2 poisoning, SO2 effect on NH3-SCR, and the enhancement of SO2 tolerance are also analyzed.

Confining Flat Ru Islands into TiO2 Lattice with the Coexisting Ru-O-Ti and Ru-Ti Bonds for Ultra-Stable Hydrogen Evolution at Amperometric Current Density and Hydrogen Oxidation at High Potential.

Effective hydrogen evolution reaction (HER) under high current density and enhanced hydrogen oxidation reaction (HOR) over a wide potential range remain challenges for Ru-based electrocatalysts because its strong affinity to the adsorbed hydroxyl (OHad) inhibits the supply of the adsorbed hydrogen (Had). Herein, the coexisting RuOTi and Ru-Ti bonds are constructed by taking TiO2 crystal confined flat-Ru clusters (F-Ru@TiO2) to cope with above-mentioned obstacles. The different electronegativity (χTi = 1.54 < χRu = 2.20 < χO = 3.44) can endow Ti sites in RuOTi bonds with more positive charge and stabilize Ru atoms of RuTi bonds with the low-valence. The strength of Ru-OHad is then weakened by the oxophilicity of positively charged Ti atom in Ru-O-Ti bonds and the stronger Ti-OHad bond could release active Ru sites, especially for low-valence Ru in RuTi bonds, to serve as exclusive Had sites. As expected, F-Ru@TiO2 shows a low HER overpotential of 74 mV at 1000mA cm-2 and an ultrahigh mass activity of 3155A gRu -1 for HOR. More importantly, F-Ru@TiO2 can tolerate the HER current density of 1000mA cm-2 for 100h and the high anodic potential for HOR up to 0.5V versus RHE.

Photocatalytic degradation of phenol and polycyclic aromatic hydrocarbons in water by novel acid soluble collagen-polyvinylpyrrolidone polymer embedded in Nitrogen-TiO2

The photocatalytic degradation of phenol, naphthalene, fluoranthene, phenanthrene, pyrene, benz[a]anthracene, and anthracene was investigated using a novel nitrogen-doped TiO2/acid-soluble collagen-polyvinyl pyrrolidone nanocomposite (N-TiO2/ASC-PVP). Characterization through X-ray diffraction (XRD), scanning electron microscopy (SEM), and transmission electron microscopy (TEM) revealed that the nanocomposite consists of spheroidal particles smaller than those of undoped TiO2. X-ray photoelectron spectroscopy (XPS) confirmed the incorporation of nitrogen within the TiO2 lattice, appearing as both substitutional nitrogen (OTiN) and interstitial nitrogen (TiON). The degradation process followed apparent first-order kinetics, with the N-TiO2/ASC-PVP calcined at 200°C and 400°C demonstrating high photocatalytic degradation efficiencies. The nanocomposite achieved a remarkable 98.6% degradation of the targeted compounds within 120 minutes at a concentration of 10 mg/L. The enhanced photocatalytic activity under visible light can be attributed to several factors: the smaller crystal size, increased surface hydroxyl groups, improved visible light absorption, and a reduced band gap energy. This N-TiO2/ASC-PVP photocatalyst shows significant potential for applications in materials science and nanotechnology, supporting advancements in environmental and energy-related fields.

Photocatalytic degradation of Diuron in water – Impact of Rh impregnation on P25 visible light activity

Significant efforts have lately been dedicated to the development of visible light activated photocatalysts for the degradation of emerging pollutants in water. This study shows the impact of Rh addition on the photocatalytic performance of TiO2 in Diuron degradation through various experimental approaches and modelling. Three samples with different Rh loading (0.5 %, 1 %, and 2 %) were synthesized, characterized, and their activities were evaluated. It was observed that the activity of RhP25 improved under white light irradiation with increasing Rh content. At low Rh loadings the Rh atoms interact with Ti and may be stabilized in the TiO2 lattice. At higher loadings Rh interacts with the O atoms forming two different clusters Rh3O4 and Rh4O6 on the TiO2 surface. This phenomenon was evidenced by DFT, XPS and XRD results. The addition of Rh induce new electronic states in the TiO2 enhancing the visible light absorption. Photocatalytic experiments revealed a threefold increase in Diuron removal under white light irradiation for 2%RhP25 compared to P25, achieving 23 % degradation in comparison with the 7 % observed for the P25 without the Rh addition. Furthermore, repeated experiments did not show significant deterioration of the activity.

Dielectric properties of (N, B) and (N, Cl) co-doped rutile TiO2 ceramics

Extensive studies on TiO2-based colossal permittivity (CP, dielectric constant ε’ >103) materials have focused on the cation doping of metal elements; however, little attention has been paid to nonmetallic dopants. Compared to metallic elements, nonmetallic atoms with small radii and high activities, such as H, C, B, and N, can be used as anion-doping elements. Their incorporation into the TiO2 lattice includes interstitial and substitutional doping, which can influence the bandgap of TiO2 and its electron transport performance differently, thereby exhibiting considerable potential in TiO2-based applications. In this study, different N-containing compounds (BN and NH4Cl) were doped into rutile TiO2, while homogeneous ceramics of single-phase rutile TiO2 were prepared via solid-state sintering. The effects of co-doping N, Cl, and N, B on the dielectric properties of rutile TiO2 ceramics were investigated. While N and Cl doping showed no considerable effect on the dielectric properties of rutile TiO2 ceramics, the co-doping of N and B doping in rutile TiO2 considerably increased the dielectric constant to >104 with suppressed tan δ in a wide frequency range from 1 kHz to 10 MHz. These ceramics exhibited excellent frequency stability (up to 100 MHz) and temperature stability (153–513 K), which outperforms most reported transition metal co-doped TiO2 ceramics, thereby highlighting the untapped potential of the non-metallic dopants in enhancing dielectric materials.

Efficient electron transport at the perovskite nanodots interface facilitates CO2 photoreduction

How to achieve controllable preparation of heterostructure and in-situ optimize the interface and internal electron transfer by a fast and economic synthesis method has become a big challenge in the practical application of photocatalysis. Herein, an island-shaped SrTiO3 (STO) perovskite nanodots and TiO2 (T) compounded S-scheme SrTiO3/TiO2 (ST) heterostructure was successfully developed. During the millisecond reaction process, the decomposed Sr2+ penetrated into the TiO2 lattice causing the lattice expansion and inducing local atomic rearrangements, resulting in the generation of STO phase. Owing to the synergy of the efficient electron transport at the perovskite nanodots interface and the stronger reduction capacity, the performance of the optimized ST1 sample is greatly improved to 86.90 μmol g−1 for CO2-to-CO and 21.31 μmol g−1 for CO2-to-CH4. The utilization of electrons reached up to 119.74 μmol g−1 h−1, which was 3.13 times higher than that of T. Detailed characterizations and density functional theory (DFT) calculations proof that the formation of intermediates HCOO− and CO32− is the key to the performance improvement critically. Overall, this work originally reports a feasible strategy for flame synthesis of S-scheme heterostructure photocatalyst.

Double nonmetal elements modified porous TiO2 homogeneous junction for efficient photocatalytic oxidation of cyclohexane

The nitrogen-doped TiO2 with mesoporous structure, anatase/rutile homogeneous junction and surface carbon species were successfully synthesized by facile hydrolysis of tetrabutyl titanate and preheating under the sealed condition, followed by a urea-aided calcination process. Interestingly, the as-obtained carbon modified TiO2 intermediates prepared by pretreating at different temperatures showed a certain photocatalytic activity for cyclohexane oxidation, and the carbon species were deposited to the surfaces of TiO2 via the Ti-O-C bond. The microstructure and photocatalytic activity of the double nonmetal elements modified porous mixed-phase TiO2 microspheres were found to depend on the preheating conditions, and nitrogen was doped into TiO2 lattice, the co-modification of nitrogen and carbon jointly improved the light absorption capacity and reduced the band gap of TiO2. The construction of a mixed-phase junction further improved the photocatalytic performance of the co-modified TiO2 compared with pure anatase or rutile TiO2. The optimal catalyst (N-TiO2-3 b) displayed efficient and stable photocatalytic performance for three cycles. When the reaction was conducted in real outdoor circumstances, the high ketone yield (206.22 μmol) and selectivity (99.92 %) were achieved. The synthetic method was simple and cheap, thus this work showed great potential for green production of fine chemicals under moderate conditions.

Precisely regulated crystalline phase of TiO2@composite G doped with Al3+: For the preparation of highly conductive, corrosion resistant conductive coatings

The development of conductive materials is crucial to the upgrading of modern science and technology industries. In recent years, the research on conductive materials synthesized based on TiO2 has mainly focused on improving the conductivity and stability of the materials. And this study, based on the high conductivity of the material, innovatively proposes a method to precisely regulate the crystal phase and morphology of TiO2 by CH3COOH and temperature together. Meanwhile, the heterostructure was successfully built by doping Al3+ into the TiO2 lattice, and a new conductive pathway (Al-O-C) was constructed. Finally, the composite G was prepared as an Al3+-doped TiO2 composite G (Al-T/G) functional material, and it was verified by first-principles calculations (DFT). The experimental results show that the Al-T/G material not only has the low surface resistance and high whiteness of TiO2, but also is endowed with more excellent resistivity (0.203 Ω·cm) and protection efficiency (92.45 %). Meanwhile, compared with the conventional antimony-doped tin dioxide (ATO) conductive materials, the Al-T/G functional materials prepared in this paper are basically harmless to the environment in the experimental process while ensuring high conductivity. Most importantly, this paper explores the bonding mechanism of Al3+-doped TiO2 conductive materials, which provides new insights and ideas in the field of dopant-modified TiO2 conductive materials.

Effect of Thiophene-Hydrazinyl-Thiazole derivative as an efficient dye sensitizer and performance enhancer of TiO2 toward rhodamine B photodegradation

Visible-light-driven photocatalysis is an eco-friendly technology for wastewater treatment, where TiO2-based photocatalysts displayed outstanding performance in this regard. Dye sensitization is a promising approach for overcoming the common drawbacks of TiO2via improving its photocatalytic performance and extending its activity to visible light. Herein, we demonstrate the synthesis of the Thiophene-Hydrazinyl-Thiazole (THT) derivative as a novel organic dye sensitizer to be employed as a visible-light antenna for TiO2 nanoparticles. The physicochemical characteristics of the as-synthesized TiO2-based nanoparticles are examined by different techniques, which revealed the successful fabrication of the proposed THT-TiO2 heterojunction. The incorporation of THT molecules on the TiO2 surface led to slight disorders and deformation in the crystal lattice of TiO2, a remarkable improvement of its absorption in the visible light as a perfect visible-light antenna in the whole visible region, and significant enhancement in the charge transfer. Rhodamine B (RhB) is used as an organic dye model to assess the photocatalytic efficiency of the as-fabricated THT-TiO2 photocatalyst which achieved almost complete degradation (>95% in 150 min) with an observed rate constant (kobs) of 0.0164 min−1; total organic carbon (TOC) measurements suggested ∼75% mineralization. THT-TiO2 achieved 2.1-fold enhancement in photodegradation% and 4.1-fold enhancement in kobs compared to the bare TiO2. THT showed good activity under visible-light irradiation (RhB degradation% was >66% in 150 min and kobs = 0.0085 min−1). The influence of the initial pH of the solution was investigated and pH 4 was the optimum pH value for suitable interaction between RhB and the surface of THT-TiO2. Radical quenching experiments were conducted to assess the crucial reactive species where the ∙OH and O2.− were the most reactive species. THT-TiO2 showed promising stability over three successive cycles. Finally, the improvement mechanism of the photocatalytic activity of THT-TiO2 was attributed to the electron injection from the excited THT (the dye sensitizer) to TiO2 and enhanced charge separation.

Enhanced photovoltaic efficiency in TiO2-based CdS quantum dot-sensitized solar cells by the introduction of ZnO:Al3+ nanoparticles

A technique to fabricate quantum dots-sensitized solar cells (QDSSCs) based on Titanium Oxide (TiO2) and Zinc Oxide (ZnO) nanoparticles (NPs) is reported. ZnO nanocubes of around 65 nm were synthesized by the sol–gel precipitation method. ZnO was doped with Al3+ to enhance the photovoltaic efficiency by promoting electron mobility to form an efficient photoelectrode added to TiO2. Current density–voltage (J-V) characterizations indicate that the addition of Al3+ doping in ZnO crystalline structure in the photoelectrode can significantly improve current densities and consequently the photoconversion efficiency (η) of the QDSSCs, achieving maximum η of 3.4 % with five ZnO nanocubes layers with a 0.0005 M Al3+ doping concentration. While with the undoped sample and bare TiO2, the obtained ήs were 2.85 and 1.93 %, respectively. The improved QDSSC photovoltaic performance was attributed to the increased light harvesting due to a large surface area by introducing Al-doped ZnO nanocubes into the available places of the TiO2 lattice. On the other hand, the increased electrical conductivity due to the Al3+ ion doped into the ZnO lattice at the divalent Zn2+ site allows electrons to move readily into the Al-doped ZnO conduction band. Additionally, according to electron lifetime studies, the Al-doped ZnO nanocubes act as a dielectric layer, enhancing the photogenerated charge extraction process due to the introduction of lattice defects, causing intermediate levels to obtain higher electron recombination resistance.

Solar-driven remediation of antibiotics in synthetic and real reverse osmosis brine: Addressing lattice oxygen demand and electron transfer for improved purification

This study investigated the significance of integrated advanced oxidation process with reverse osmosis (RO) to ensure the purification and elimination of micropollutants, primarily pharmaceuticals prior to the discharge of brine to the environment. To envisage this, TiO2 based solar driven photocatalysis was employed, highlighting the crucial role of oxygen vacancy formation in the lattice of TiO2 for enhancing the purification of antibiotic contaminants from RO brine. The study elucidated how variations in oxygen environments such as oxygen rich yellow TiO2 (Y-TiO2) and oxygen vacancy black TiO2 (B-TiO2) influence photodegradation reaction kinetics taking ofloxacin (OFX) and tetracycline (TC) as model pollutants. The B-TiO2 exhibited 8.5 times higher photodegradation for OFX compared to Y-TiO2, proving significance in tuning of oxygen environment in lattice. The photodegradation efficiency plot showcases B-TiO2′s efficacy, demonstrating 99.8 % and 99.4 % for OFX and TC, respectively. Additionally, the study investigated the photocatalytic degradation mechanism, identifying predominant charge carriers and reactive species involved, while also assessing the durability of photodegradation processes. The impact of pH on the photocatalytic performance of B-TiO2 in degrading antibiotics explored, spanning pH levels from 2.5 to 10.5. An exploration on band alignment formation in B-TiO2 explains the effectiveness of it over Y-TiO2. Lastly, efficacy of B-TiO2 in degrading antibiotics in real RO brine with high level of salinity (60,200 ppm TDS) is demonstrated, which resulted with photodegradation efficiency of 31.25 % for OFX and 67.8 % for TC, proving applicability of integrated system as a sustainable purification approach. Moreover, the blockage of chloride ions quenching demonstrated improvements in photodegradation emphasizing the influence of chloride ions in high saline conditions.

Simultaneously activating molecular oxygen and surface lattice oxygen on Pt/TiO2 for low-temperature CO oxidation

Developing high-performance Pt-based catalysts with low Pt loading is crucial but challenging for CO oxidation at temperatures below 100 °C. Herein, we report a Pt-based catalyst with only a 0.15 wt% Pt loading, which consists of Pt–Ti intermetallic single-atom alloy (ISAA) and Pt nanoparticles (NP) co-supported on a defective TiO2 support, achieving a record high turnover frequency of 11.59 s–1 at 80 °C and complete conversion of CO at 120 °C. This is because the coexistence of Pt–Ti ISAA and Pt NP significantly alleviates the competitive adsorption of CO and O2, enhancing the activation of O2. Furthermore, Pt single atom sites are stabilized by Pt–Ti ISAA, resulting in distortion of the TiO2 lattice within Pt–Ti ISAA. This distortion activates the neighboring surface lattice oxygen, allowing for the simultaneous occurrence of the Mars-van Krevelen and Langmuir–Hinshelwood reaction paths at low temperatures.

A handy way for forming N-doped TiO2/carbon from pectin and d,l-serine hydrazide hydrochloride

N-doped TiO2/carbon composites (N-TiPC) have shown excellent photodegradation performances to the organic contaminants but are limited by the multistage preparation (i.e., preparation of porous carbon, preparation of N-doped TiO2, and loading of N-doped TiO2 on porous carbon). Here, we develop a handy way by combining the Pickering emulsion-gel template route and chelation reaction of polysaccharides. The N-TiPC is obtained by calcinating pectin/Dl-serine hydrazide hydrochloride (SHH)-Ti4+ chelate and is further described by modern characterization techniques. The results show that the N atom is successfully doped into the TiO2 lattice, and the bandgap value of N-TiPC is reduced to 2.3 eV. Moreover, the particle size of N-TiPC remains about 10 nm. The configurations of the composites are simulated using DFT calculation. The photocatalytic experiments show that N-TiPC has a high removal efficiency for methylene blue (MB) and oxytetracycline hydrochloride (OTC-HCL). The removal ratios of MB (20 mg/L, 50 mL) and OTC-HCL (30 mg/L, 50 mL) are 99.41 % and 78.29 %, respectively. The cyclic experiments show that the photocatalyst has good stability. Overall, this study provides a handy way to form N-TiPC with enhanced photodegradation performances. It can also be promoted to other macromolecules such as cellulose and its derivatives, sodium alginate, chitosan, lignin, etc.