Advances in photocatalytic disinfection of bacteria: Development of photocatalysts and mechanisms

Photocatalysis has attracted worldwide attention due to its potential in solar energy conversion. As a “green” advanced oxidation technology, it has been extensively used for water disinfection and wastewater treatment. This article provides a review of the recent progress in solar energy-induced photocatalytic disinfection of bacteria, focusing on the development of highly efficient photocatalysts and their underlying mechanisms in bacterial inactivation. The photocatalysts are classified into TiO₂-based and non-TiO₂-based systems, as TiO₂ is the most investigated photocatalyst. The synthesis methods, modification strategies, bacterial disinfection activities and mechanisms of different types of photocatalysts are reviewed in detail. Emphasis is given to the modified TiO₂, including noble metal deposition, non-metal doping, dye sensitization and composite TiO₂, along with typical non-TiO₂-based photocatalysts for bacterial disinfection, including metal oxides, sulfides, bismuth metallates, graphene-based photocatalysts, carbon nitride-based photocatalysts and natural photocatalysts. A simple and versatile methodology by using a partition system combined with scavenging study is introduced to study the photocatalytic disinfection mechanisms in different photocatalytic systems. This review summarizes the current state of the work on photocatalytic disinfection of bacteria, and is expected to offer useful insights for the future development in the field.     

Graphitic carbon nitride-based photocatalysts in the applications of environmental catalysis

Semiconductor photocatalytic technology has shown great prospects in converting solar energy into chemical energy to mitigate energy crisis and solve environmental pollution problems. The key issue is the development of high-efficiency photocatalysts. Various strategies in the state-of-the-art advancements, such as heterostructure construction, heteroatom doping, metal/single atom loading, and defect engineering, have been presented for the graphitic carbon nitride (g-C₃N₄)-based nanocomposite catalysts to design their surface chemical environments and internal electronic structures to make them more suitable for different photocatalytic applications. In this review, nanoarchitecture design, synthesis methods, photochemical properties, potential photocatalytic applications, and related reaction mechanisms of the modified high-efficiency carbon nitride-based photocatalysts were briefly summarized. The superior photocatalytic performance was identified to be associated with the enhanced visible-light response, fast photoinduced electron-hole separation, efficient charge migration, and increased unsaturated active sites. Moreover, the further advance of the visible-light harvesting and solar-to-energy conversions are proposed.     

In situ preparation of visible-light-driven carbon quantum dots/NaBiO3 hybrid materials for the photoreduction of Cr(VI)

In this study, different carbon quantum dots (CQDs)/NaBiO₃ hybrid materials were synthesized as photocatalysts to effectively utilize visible light for the photocatalytic degradation of contaminants effectively. These hybrid materials exhibit an enhanced photocatalytic reduction of hexavalent chromium (Cr(VI)) in the aqueous medium. Zero-dimensional nanoparticles of CQDs were embedded within the two-dimensional NaBiO₃ nanosheets by the hydrothermal process. Compared with that of the pure NaBiO₃ nanosheets, the photocatalytic performance of the hybrid catalysts was significantly high and 6 wt.% CQDs/NaBiO₃ catalyst exhibited better photocatalytic performance. We performed the first-principles density functional theory calculations to study the interfacial properties of pure NaBiO₃ nanosheets and hybrid photocatalysts, and confirmed the CQDs played an important role in the CQDs/NaBiO₃ composites. The experimental results indicated that the enhanced reduction of Cr(VI) was probably due to the high loading of CQDs (electron acceptor) on NaBiO_3, which made NaBiO₃ nanomaterials to respond in visible light and significantly improved their electron-hole separation efficiency.     

Combined effects of adsorption and photocatalysis by hybrid TiO2/ZnO-calcium alginate beads for the removal of copper

The use of nanosized titanium dioxide(TiO_2) and zinc oxide(ZnO) in the suspension form during treatment makes the recovering and recycling of photocatalysts difficult.Hence,supported photocatalysts are preferred for practical water treatment applications.This study was conducted to investigate the efficiency of calcium alginate(CaAlg) beads that were immobilized with hybrid photocatalysts,TiO_2/ZnO to form TiO_2/ZnO-CaAlg.These immobilized beads,with three different mass ratios of TiO_2:ZnO(1:1,1:2,and 2:1) were used to remove Cu(Ⅱ) in aqueous solutions in the presence of ultraviolet light.These beads were subjected to three cycles of photocatalytic treatment with different initial Cu(Ⅱ) concentrations(10-80 ppm).EDX spectra have confirmed the inclusion of Ti and Zn on the surface of the CaAlg beads.Meanwhile,the surface morphology of the beads as determined using SEM,has indicated differences of before and after the photocatalytic treatment of Cu(Ⅱ).Among all three,the equivalent mass ratio TiO_2/ZnO-CaAlg beads have shown the best performance in removing Cu(Ⅱ) during all three recycling experiments.Those TiO_2/ZnO-CaAlg beads have also shown consistent removal of Cu,ranging from 7.14-52.0 ppm(first cycle) for initial concentrations of10-80 ppm.In comparison,bare CaAlg was only able to remove 6.9-48 ppm of similar initial Cu concentrations.Thus,the potential use of TiO_2/ZnO-CaAlg beads as environmentally friendly composite material can be further extended for heavy metal removal from contaminated water.     

可见光响应漂浮式微球光催化剂及其光降解模拟海水中苯酚

为了将光催化技术应用于有机物污染海水的治理,本文首先利用水热还原得到了具有可见光响应的还原商用P25光催化剂,而后将还原后的P25作为活性组分负载在透明的有机玻璃空心微球表面,制成漂浮式微球光催化剂.还原后的P25的表征结果表明,水热条件下金属还原作用会将P25中少量Ti~(4+)还原成Ti~(3+),同时催化剂表面还形成了无序化-内部结晶的核壳结构.这两种结构变化都会显著拓展还原P25催化剂的可见光响应.含苯酚模拟污染海水的光降解实验发现,降解低浓度苯酚时,漂浮型微球光催化剂显示了优异的降解效率,降解5 h的去除率达到了95%以上.由于还原P25光催化剂的稳定性并且漂浮式微球光催化剂能简易回收,在多次重复实验中微球光催化剂都可以保持较高的催化活性.     

Tricrystalline TiO2 with enhanced photocatalytic activity and durability for removing volatile organic compounds from indoor air

It is important to develop efficient and economic techniques for removing volatile organic compounds(VOCs) in indoor air. Heterogeneous Ti O_2-based semiconductors are a promising technology for achieving this goal. Anatase/brookite/rutile tricrystalline Ti O_2 with mesoporous structure was synthesized by a low-temperature hydrothermal route in the presence of HNO_3.The obtained samples were characterized by X-ray diffraction and N_2 adsorption–desorption isotherm. The photocatalytic activity was evaluated by photocatalytic decomposition of toluene in air under UV light illumination. The results show that tricrystalline Ti O_2 exhibited higher photocatalytic activity and durability toward gaseous toluene than bicrystalline Ti O_2,due to the synergistic effects of high surface area, uniform mesoporous structure and junctions among mixed phases. The tricrystalline Ti O_2 prepared at R HNO_3= 0.8, containing80.7% anatase, 15.6% brookite and 3.7% rutile, exhibited the highest photocatalytic activity,about 3.85-fold higher than that of P25. The high activity did not significantly degrade even after five reuse cycles. In conclusion, it is expected that our study regarding gas-phase degradation of toluene over tricrystalline Ti O_2 will enrich the chemistry of the Ti O_2-based materials as photocatalysts for environmental remediation and stimulate further research interest on this intriguing topic.     

Tricrystalline TiO2 with enhanced photocatalytic activity and durability for removing volatile organic compounds from indoor air

It is important to develop efficient and economic techniques for removing volatile organic compounds (VOCs) in indoor air. Heterogeneous TiO₂-based semiconductors are a promising technology for achieving this goal. Anatase/brookite/rutile tricrystalline TiO₂ with mesoporous structure was synthesized by a low-temperature hydrothermal route in the presence of HNO₃. The obtained samples were characterized by X-ray diffraction and N₂ adsorption–desorption isotherm. The photocatalytic activity was evaluated by photocatalytic decomposition of toluene in air under UV light illumination. The results show that tricrystalline TiO₂ exhibited higher photocatalytic activity and durability toward gaseous toluene than bicrystalline TiO₂, due to the synergistic effects of high surface area, uniform mesoporous structure and junctions among mixed phases. The tricrystalline TiO₂ prepared at R_HNO3 = 0.8, containing 80.7% anatase, 15.6% brookite and 3.7% rutile, exhibited the highest photocatalytic activity, about 3.85-fold higher than that of P25. The high activity did not significantly degrade even after five reuse cycles. In conclusion, it is expected that our study regarding gas-phase degradation of toluene over tricrystalline TiO₂ will enrich the chemistry of the TiO₂-based materials as photocatalysts for environmental remediation and stimulate further research interest on this intriguing topic.     

Carbon dioxide adsorption behaviors of aluminum-pillared montmorillonite-supported alkaline earth metals

The Al-pillared montmorillonite-supported alkaline earth metal 5M/Al-PILC (PILC = pillared clay, M = Mg, Ca, Sr, and Ba) and xMg/Al-PILC (x = 1, 3, 5, and 7 wt.%) samples were prepared using an impregnation method. Physical properties of the materials were determined by means of X-ray diffraction (XRD) and N₂ adsorption-desorption, and their CO₂ adsorption behaviors were investigated using the thermogravimetric analyzer (TG), CO₂ temperature-programmed desorption (CO₂-TPD), and in situ diffuse reflectance infrared transform spectroscopy (in situ-DRIFTS) techniques. It is shown that 5Mg/Al-PILC possessed the highest CO₂ adsorption capacity (2.559 mmol/g). The characterization results indicate that Al-pillaring increased the specific surface area of montmorillonite, which was beneficial for the adsorption of CO₂. The CO₂ adsorption process on the sample was mainly chemical adsorption, and alkalinity was the main factor influencing its adsorption capacity. The alkalinity of the sample was enhanced by loading an appropriate amount of alkaline earth metal, and the adsorbed CO₂ was present in the form of bicarbonate and carbonate. In addition, the 5Mg/Al-PILC sample exhibited an excellent regeneration efficiency. We believe that the outcome of this research would provide a good option for developing highly effective CO₂ adsorption materials.     

C3N4/BiOBr复合可见光催化剂的性能及其作用机制

利用水热合成法制备了C_3N_4/BiOBr复合可见光催化剂,通过XRD、FT-IR、SEM、DRS、PL等手段对催化剂的物相组成和光化学性能进行了系统表征,利用对罗丹明B(RhB)的降解实验评价了催化剂在可见光照下的光催化降解活性和稳定性并通过ESR分析和自由基捕获实验探究了RhB的光催化降解机制.结果表明,水热合成法可成功制备结晶性能良好的C_3N_4/BiOBr复合可见光催化剂;C_3N_4的复合降低了BiOBr光催化剂的电子-空穴的复合,提高了光催化降解活性,其中15%C_3N_4/BiOBr的活性最佳,可见光照18 min后RhB的脱色率达100%,较纯BiOBr提高了1.5倍,且重复使用5次后仍具有较高的光催化降解活性;复合催化剂光催化降解RhB过程中参与降解的主要活性物种为空穴(h~+)和超氧自由基(·O_2~-),其中h~+影响更为显著.     

A new method for assessing CO2-emissions from container terminals: a promising approach applied in Rotterdam

At present, the notion is generally accepted that societies have to combat climate change. The reduction of CO₂-emissions, an important cause for global warming, has become a priority, and consequently there is increasing pressure on governments and industries to come forward with initiatives to reduce CO₂-emissions. This is highly relevant for the transport sector, as the share of transportation is still increasing, while other sectors are reducing their CO₂-footprint. The main purpose of this paper is to present a methodology to analyse the CO₂-emissions from container terminals, illustrated by the Port of Rotterdam.The objective of this paper is twofold. Firstly, the development of a methodology to analyse and gain a better understanding of the CO₂-emissions by container terminals in port areas is described. Secondly, the most effective solutions to reduce CO₂-emissions by container terminals in port areas are identified. The study provides insight into the processes of container transshipment at the terminals and the contribution of these processes to the CO₂-emissions of the container terminals. Using these insights, potential solutions to reduce the CO₂ at the terminals are identified and policy proposals are made for the operators of existing terminals and for governments.The most effective measure for CO₂ reduction is undoubtedly the adaptation of the terminal layout as in the example of the Rotterdam Shortsea Terminal. This makes it possible to reduce the CO₂-emissions of the current terminals by nearly 70 per cent. The other perspective is the incorporation of mixing 30 per cent biofuels with the presently used diesel. This results in a reduction of CO₂-emissions by between 13 and 26 per cent per terminal and a reduction of the emissions of the total container sector by 21 per cent. On the basis of these findings, concrete recommendations are made to reducing CO₂-emissions at container terminals.