PbO-PbI2复合物膜转化的CH3NH3PbI3钙钛矿薄膜及其光电特性

有机-无机卤化物钙钛矿是一类优异的光电材料. 在过去四年内, 基于有机-无机卤化物钙钛矿的光电器件实现了超过15%的光电转换效率. 而有机-无机卤化物钙钛矿材料的可控制备是保证其在光电器件中应用的基础. 本文采用新的沉积方法在玻璃衬底表面制备了一种典型的有机-无机卤化物钙钛矿CH₃NH₃PbI₃薄膜. 其制备过程是: 采用超声辅助的连续离子吸附与反应法在玻璃衬底表面沉积PbO-PbI₂复合物膜, 之后与CH3NH3I蒸汽在110 ℃环境下反应, 将PbO-PbI₂复合物膜转化成CH₃NH₃PbI₃钙钛矿薄膜. 对CH₃NH₃PbI₃薄膜的微观结构, 结晶性及其光电性能等进行了表征. 结果表明, CH₃NH₃PbI₃薄膜呈晶态, 具有典型的钙钛矿晶体结构. 薄膜表面形貌均匀, 晶粒尺寸超过400 nm. 在可见光范围, CH₃NH₃PbI₃薄膜透过率低于10%, 能带宽度为1.58eV. 电学性能研究表明CH₃NH₃PbI₃薄膜表面电阻率高达1000 MΩ. 高表面电阻率表明CH₃NH₃PbI₃薄膜具有一定的介电性能, 其介电常数(ε_r)在100 Hz时达到155. 本研究提出了一种制备高质量CH₃NH₃PbI₃钙钛矿薄膜的新方法, 所得CH₃NH₃PbI₃薄膜可望在光、电及光电器件中得到应用.     

水分辅助对无机钙钛矿CsPbI3薄膜结晶的影响

利用水分辅助晶粒溶解重结晶策略提高全无机铯铅碘钙钛矿(CsPbI₃)薄膜的质量, 探究了退火过程中不同湿度条件对薄膜结晶质量的影响, 并从形貌结构、 缺陷复合以及光伏性能等方面进行了研究. 结果表明, 相比于相对湿度(RH)为0%组CsPbI₃薄膜明显的晶界空隙, 适当的湿度退火有助于晶粒间更致密地结合, 晶界的减少进而可抑制载流子非辐射复合; 湿度过大则会形成较粗糙的表面形貌, 影响界面接触. 实验结果表明, 7%RH下CsPbI₃薄膜中缺陷明显减少, 非辐射复合得到抑制, 载流子寿命增加; 光伏性能测试结果显示, 开路电压(V_oc)和填充因子(FF)显著增大, 并获得了15.28%的光电转换效率(PCE).     

基于易升华添加剂辅助合成纯相富铯(CH(NH2)2)xCs1−xPbI3 钙钛矿

钙钛矿材料化学组分是决定钙钛矿太阳能电池效率和稳定性的关键,纯无机钙钛矿CsPbI₃具有相对较好的热稳定性和光稳定性,但由于Cs⁺具有较小的离子半径而导致无机钙钛矿相不稳定。最近研究发现富铯FA_xCs_1?xPbI₃钙钛矿具有相对稳定的相结构,且可以很大程度上保持无机钙钛矿材料的热稳定性和光照稳定性,是一种非常具有前景的钙钛矿材料体系。目前这种富铯的FA_xCs_1?xPbI₃材料合成是通过引入过量有机组分FAI实现的,其中FAI一方面充当钙钛矿的掺杂剂,另一方面过量的FAI充当添加剂。由于其具有较高的升华温度,后续需要较高的温度使过量的FAI升华,实际上这在实验上很难实现对FAI升华量的精确控制。本文重点研究具有低升华温度的胺类,如碘甲胺(MAI)、碘化二甲胺(DMAI)、碘化乙胺(EAI)、碘化胺(NH₄I)和醋酸甲脒(FAAC),作为添加剂制备富铯FA_xCs_1?xPbI₃钙钛矿材料体系的可行性,这一方面可以有效降低钙钛矿薄膜的热处理温度;另一方面可拓宽的制备纯相钙钛矿成分的窗口期,这对大面积制备纯相富铯FA_xCs_1?xPbI₃钙钛矿薄膜尤为重要。结果表明MAI和DMAI可以作为合成FA_xCs_1?xPbI₃钙钛矿材料的有效添加剂,其与PbI2间较强的作用力可以促进Cs₄PbI₆的形成并有效抑制δ-CsPbI₃副产物的生成。合适的升华温度可以使薄膜在保持钙钛矿相结构的同时在较低温度升华去除过量的添加剂,最终实现在相对温和的条件下制备纯相富铯FA_xCs_1?xPbI₃钙钛矿材料。     

控制碘化铅形貌两步连续刮涂法大面积制备甲脒基钙钛矿薄膜（英文）

钙钛矿太阳能电池在实现高性能光伏器件方面展现出巨大的商业化应用前景,但面临着一个最主要的挑战是开发工业化规模生产的大面积高质量钙钛矿薄膜制备工艺。在本研究中,为解决大面积印刷难题,通过两步连续刮涂法制备甲脒基钙钛矿吸光层。两步法中第一步沉积的PbI₂很容易形成致密的薄膜,这将导致后续沉积的有机胺盐无法和PbI₂充分完全反应,在钙钛矿薄膜中残留PbI₂,这会严重影响载流子的传输。为了实现理想的多孔PbI₂薄膜结构,我们通过在PbI₂前驱体溶液中引入四亚甲基亚砜(THTO)。通过形成PbI₂·THTO络合物,PbI₂的结晶过程被有效控制,易形成片状的PbI₂晶粒并沿着垂直基底方向上排列,得到了理想的纳米通道。这为后续的有机胺盐渗入提供了理想的纳米通道。最终5cm×5cm模组实现了18.65%的功率转化效率,并具有出色的存储和热稳定性。这一结果展现了两步连续刮涂法策略在制备大面积钙钛矿太阳能电池方面具备一定的优势。     

控制碘化铅形貌两步连续刮涂法大面积制备甲脒基钙钛矿薄膜

钙钛矿太阳能电池在实现高性能光伏器件方面展现出巨大的商业化应用前景,但面临着一个最主要的挑战是开发工业化规模生产的大面积高质量钙钛矿薄膜制备工艺。在本研究中,为解决大面积印刷难题,通过两步连续刮涂法制备甲脒基钙钛矿吸光层。两步法中第一步沉积的PbI₂很容易形成致密的薄膜,这将导致后续沉积的有机胺盐无法和PbI₂充分完全反应,在钙钛矿薄膜中残留PbI₂,这会严重影响载流子的传输。为了实现理想的多孔PbI₂薄膜结构,我们通过在PbI₂前驱体溶液中引入四亚甲基亚砜(THTO)。通过形成PbI₂·THTO络合物,PbI₂的结晶过程被有效控制,易形成片状的PbI₂晶粒并沿着垂直基底方向上排列,得到了理想的纳米通道。这为后续的有机胺盐渗入提供了理想的纳米通道。最终5 cm × 5 cm模组实现了18.65%的功率转化效率,并具有出色的存储和热稳定性。这一结果展现了两步连续刮涂法策略在制备大面积钙钛矿太阳能电池方面具备一定的优势。     

电泳法制备的致密氧化锡薄膜及其在高稳定性钙钛矿太阳能电池中的应用

在平面型钙钛矿太阳能电池中常采用SnO₂作为电子传输层材料,相应的SnO₂薄膜常采用溶液旋涂法制备。但是由于前驱液中的纳米颗粒可能会发生部分团聚、基底和溶液难以完全避免灰尘等杂质颗粒混入,且最佳的SnO₂电子传输层的厚度通常仅有约20 nm,所以这种方法制备的电子传输层难以保证严格致密和无纳米针孔。在本工作中,我们报道了一种电泳沉积制备致密SnO₂薄膜的方法,并用其有效地提高了钙钛矿太阳能电池的光电转换效率和工况稳定性。通过电泳法,表面带负电荷的SnO₂纳米颗粒在电场的作用下沉积到氧化铟锡(ITO)阳极表面,这种方法得到的薄膜比旋涂法制备的更为致密。将其应用于n-i-p结构的钙钛矿太阳能电池中,能够使得暗电流降低并抑制载流子的非辐射复合,从而提高电池的短路电流和开路电压,进而实现更高的光电转换效率(从18.17%提高到19.52%),且能消除迟滞效应。更重要的是,长期工况稳定性测试表明基于电泳-旋涂法制备的器件在1个太阳的光照下、最大功率点处连续工作960 h后,仍然能够保持71%的初始效率;然而基于旋涂法制备的器件在工作100 h后即降低到初始效率的70%。本工作提供了一种全新的SnO₂电子传输层的制备方法,显著地提高了器件性能和工况稳定性,后续有望应用于制备大面积器件和电池模组。     

多孔TiO2层厚度对钙钛矿太阳能电池性能的影响

制备了基于不同厚度(100～500 nm)多孔TiO₂层的钙钛矿太阳能电池, 并用SEM、XRD、紫外-可见吸收谱、电压-电流曲线、电化学阻抗谱进行了表征. 研究发现, 多孔TiO₂薄膜厚度对电池性能有很大影响, 即随着多孔TiO₂薄膜厚度的增加, 短路电流略有提高, 而开路电压和填充因子呈下降趋势;但同时, 较厚的多孔TiO₂薄膜可有效减弱滞回现象. 进一步采用电化学阻抗谱和暗态电流-电压曲线研究了载流子复合. 电化学阻抗谱表明, 膜厚增加会增大载流子复合但不会改变二极管理想因子. 通过拟合暗态电流-电压曲线得到反向饱和电流, 随着膜厚增加, 反向饱和电流会增大, 从而加剧了载流子复合. 通过优化多孔TiO₂薄膜厚度, 基于150 nm多孔TiO₂薄膜钙钛矿电池的认证效率达到15.56%.     

溶液法生长大面积超薄钙钛矿单晶薄膜

卤化物钙钛矿由于其独特的光电性质,在薄膜光电子器件领域具有极大潜力1。虽然许多工作都集中在多晶钙钛矿材料上,但单晶钙钛矿比多晶具有更低的缺陷态密度、更好的载流子输运能力和更高的稳定性2,3,可以有有效减少甚至消除载流子输运过程中的散射损失以及在晶界处的非辐射性复合4。采用单晶钙钛矿薄膜作为器件活性层被认为是进一步提高钙钛矿光电子器件性能的理想方案。目前,研究报道的钙钛矿单晶薄膜生长方法主要通过化学气相沉积和溶液空间限制法5,6,然而,所制备的薄膜厚度往往较厚,相应的器件性能也没有多晶薄膜的器件高7,因此,生长高质量的超薄大面积钙钛矿单晶薄膜至关重要。     

铜铁矿CuCrO2空穴传输材料增强反式钙钛矿太阳能电池的光电压(英文)

聚3,4-亚乙基二氧噻吩/聚苯乙烯磺酸具有良好的透光性和柔韧性以及较好的热稳定性,是反式钙钛矿太阳能电池常用的空穴传输材料,但聚3,4-亚乙基二氧噻吩/聚苯乙烯磺酸的酸性和吸湿性不可避免地会影响钙钛矿太阳能电池的长期稳定性,其能级与钙钛矿材料能级的不完全匹配会造成钙钛矿太阳能电池的开路电压较低.本文应用水热法合成的p型铜铁矿CuCrO₂纳米颗粒作为反式结构[(FA PbI₃)_0.87(MAPbBr₃)_0.13]_0.92(CsPbI₃)_0.08基底钙钛矿太阳能电池的空穴传输材料.结果表明,反式结构钙钛矿太阳能电池的开路电压以聚3,4-亚乙基二氧噻吩/聚苯乙烯磺酸为空穴传输材料时的908 mV提升至以CuCrO₂为空穴传输材料时的1020 mV.紫外光电子能谱测试表明CuCrO₂与钙钛矿材料之间的能级匹配优于聚3,4-亚乙基二氧噻吩/聚苯乙烯磺酸与钙钛矿之间的能级匹配,电化...     

类石墨烯二硫化钨薄膜的化学气相沉积法制备及其应用

类石墨烯过渡金属硫属化合物如MoS₂、WS₂、MoSe₂、WSe₂等因为具有层数依赖的带隙结构而受到了广泛关注。尤其是本征态的WS₂为双极性半导体,它同时具有n型和p型电输运特性,有望在电子电路、存储器件、光电探测和光伏器件方面得以广泛应用。近年来,化学气相沉积技术已经被广泛用于制备大面积二维硫属化合物(如MoS₂, MoSe₂, WS₂ 和WSe₂)原子层薄膜。目前关于其他二维材料体系的综述文献介绍较多,但是针对WS₂介绍的综述文献还鲜有报道。因此,本文综述了类石墨烯WS₂薄膜的化学气相沉积法制备和相关器件的国内外研究进展,讨论了WS₂薄膜的化学气相沉积法制备机理及生长因素如硫粉含量、载气的成分、反应温度、基底材料等对薄膜成膜质量的影响,介绍了WS₂薄膜在晶体管、光电器件及与其他二维材料构成的异质结构器件的最新研究成果,并对可能存在的问题进行了分析和述评。     

镶嵌于NH2-MIL-125 (Ti)衍生氮掺多孔碳中的花状超细纳米TiO2作为高活性和稳定性的锂离子电池负极材料

由于具有高安全性和优异的循环稳定性,二氧化钛(TiO₂)作为负极材料被广泛地应用于锂离子电池领域。但是较差的导电性和离子传输速率限制了TiO₂的进一步应用和发展。鉴于此,我们以花状NH₂-MIL-125 (Ti)为前驱体和硬模板,成功合成出了具有花状结构的超细纳米TiO₂/多孔氮掺杂碳片(N-doped porous carbon)复合物(记为FL-TiO₂/NPC)。过程中所制备的纳米TiO₂-金属有机构架(Ti-MOF)展现出由二维褶皱多孔纳米片堆积、组装而成的花状结构。一方面,二维褶皱纳米片包含TiO₂纳米颗粒可以增大活性物质与电解液的接触面积;另一方面,氮掺杂多孔碳基体可以提高整体复合物的导电性和结构完整性。将所获得的FL-TiO₂/NPC作为负极组装成的锂半电池, 在0.5 A·g^-1、300圈后仍有384.2 mAh·g^-1以及在1 A·g^-1、500圈仍有279.1 mAh·g^-1的比容量。进一步性能测试表明,在2 A·g^-1、2000圈长循环测试后,其仍能保持256.5 mAh·g^-1的比容量和接近100%的库伦效率。该优异的电化学活性和稳定性主要起源于材料独特的花状结构。我们的合成策略为今后制备高储锂性能的金属氧化物/多孔氮掺杂碳负极提供了一种新的思路。     

Mixed-phase Mesoporous TiO2 Film for High Efficiency Perovskite Solar Cells

Mesoporous scaffold structures have played great roles in halide perovskite solar cells(PSCs),due to the excellent photovoltaic performance and commercial perspective of mesoporous PSCs.Here,we reported a mixed-phase TiO2 mesoporous film as an efficient electron transport layer(ETL)for mesoporous perovskite solar cells.Due to the improved crystal phase,fihn thickness and nanopartMe size of TiO2 layer,which were controlled by varying the one-step hydrothermal reaction time and annealing time,the PSCs exhibited an outstanding short circuit photocurrent density of 25.27 mA/cm^2,and a maximum power conversion efficiency(PCE)of 19.87%.It is found that the ultra-high Jsc attributes to the excellent film quality,light capturing and excellent electron transport ability of mixed-phase TiO2 mesoporous film.The results indicate that mix-phase mesoporous metal oxide fihns could be a promising candidate for producing effective ETLs and high efficiency PSCs.     

核壳结构NH2-UiO-66@TiO2的制备及其可见光下的甲苯降解性能研究

Metal-organic frameworks (MOFs) are of significant interest for photocatalysis using visible light, but they are typically limited by the instability and high recombination ratio of photoexcited pairs. Integrating MOFs into an inorganic semiconductor is one of the most widespread methods to promote their activity. In this study, a core-shell structured MOF@TiO₂ (NH₂-UiO-66@TiO₂) was synthesized as an efficient photocatalyst for the degradation of toluene. Pristine NH₂-UiO-66 was synthesized by a hydrothermal method as the core, which was then coated with an amorphous TiO₂ shell. Compared with pristine NH₂-UiO-66 and other samples prepared by the direct mixing of NH₂-UiO-66 and TiO₂, NH₂-UiO-66@TiO₂ exhibited a higher degradation rate of toluene. Using NH₂-UiO-66@TiO₂ as a catalyst, the degradation efficiency of toluene reached 76.7% within 3 h, which is 1.48 times higher than that of NH₂-UiO-66. The degradation performance was also stable in four repeated reuse experiments, and the slight deactivation was reactivated after washing with ethanol. A series of characterization methods were used to determine the physicochemical properties of NH₂-UiO-66@TiO₂, including X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). Using the measured physicochemical properties, the photocatalytic mechanism of NH₂-UiO-66@TiO₂ was explored. NH₂-UiO-66 is an ideal photocatalyst, with visible-light response and a huge specific surface area (914.9 m²·g^-1), which is favorable for the utilization of sunlight as well as the absorption of pollutants in indoor air. In addition, a new interface formed between the two components (NH₂-UiO-66 and TiO₂), which efficiently broaden the light absorption area and enhanced the utilization of photogenerated species. The photogenerated holes and electrons could transfer through the interlayer as soon as they were formed. It is speculated that holes would transfer to the HOMO of NH₂-UiO-66, and then combine with H₂O molecules to form hydroxyl radicals (·OH). At the same time, more electrons tended to combine with oxygen molecules in the conduction band of TiO₂ rather than recombine with holes. Consequently, the recombination rate of electrons and holes decreased, while the quantity of oxygen radicals and hydroxyl radicals increased. Toluene was efficiently oxidized by these two types of radicals. Owing to the outstanding properties mentioned above, the strategy of constructing NH₂-UiO-66@TiO₂ is considered to be an effective approach. This work may provide new insights into the design of core-shell structured MOF@photocatalysts for the photocatalytic degradation of indoor air pollutants.      

微波热冲快速制备二维多孔La0.2Sr0.8CoO3钙钛矿用于高效电催化析氧反应

析氧反应(OER)被认为是电解水的关键限制步骤,已被广泛作为清洁能源方式用于解决能源和环境问题。钙钛矿氧化物(ABO₃)具有可调的电子结构、高灵活性的元素组成,能在OER中表现出良好的催化活性。然而,钙钛矿氧化物的合成通常需要经历长时间的高温,极易导致金属的聚集和影响材料的本征活性。气相微波技术可以显著缩短热处理时间,从而减少相关的碳排放。这项技术不仅解决了对碳中性过程日益增长的需求,而且还增加了对合成的控制,以避免产品的不良团聚。本文采用微波热冲法快速制备了二维(2D)多孔La_0.2Sr_0.8CoO₃钙钛矿。伴随微波过程的快速熵增可以有效地暴露La_0.2Sr_0.8CoO₃结构中丰富的活性位点。此外,高能微波冲击过程可以精准地将Sr²⁺引入到LaCoO₃的晶格中,通过增加Co的氧化态来增加氧空位量。这种锶元素取代镧引入的氧空位能极大提高催化剂的本征催化活性。对于碱性电解液中的OER应用,制备的La_0.2Sr_0.8CoO₃在10 mA∙cm⁻²下展现出了360 mV的过电位,Tafel斜率为76.6 mV∙dec⁻¹。且在经历30000秒的长时间循环测试后仍能维持初始电流密度的97%。这项研究为高活性二维钙钛矿的合成提供了一种简便、快速的策略。     

羧基功能化石墨烯增强TiO2光催化产氢性能

The use of semiconductor photocatalysts (CdS, g-C₃N₄, TiO₂, etc.) to generate hydrogen (H₂) is a prospective strategy that can convert solar energy into hydrogen energy, thereby meeting future energy demands. Among the numerous photocatalysts, TiO₂ has attracted significant attention because of its suitable reduction potential and excellent chemical stability. However, the photoexcited electrons and holes of TiO₂ are easily quenched, leading to limited photocatalytic performance. Furthermore, graphene has been used as an effective electron cocatalyst in the accelerated transport of photoinduced electrons to enhance the H₂-production performance of TiO₂, owing to its excellent conductivity and high charge carrier mobility. For an efficient graphene-based photocatalyst, the rapid transfer of photogenerated electrons is extremely important along with an effectual interfacial H₂-production reaction on the graphene surface. Therefore, it is necessary to further optimize the graphene microstructures (functionalized graphene) to improve the H₂-production performance of graphene-based TiO₂ photocatalysts. The introduction of H₂-evolution active sites onto the graphene surface is an effective strategy for the functionalization of graphene. Compared with the noncovalent functionalization of graphene (such as loading Pt, MoS_x, and CoS_x on the graphene surface), its covalent functionalization can provide a strong interaction between graphene and organic molecules in the form of H₂-evolution active sites that are produced by chemical reactions. In this study, carboxyl-functionalized graphene (rGO-COOH) was successfully modified via ring-opening and esterification reactions on the TiO₂ surface by using an ultrasound-assisted self-assembly method to prepare a high-activity TiO₂/rGO-COOH photocatalyst. The Fourier transform infrared (FTIR) spectra, X-ray photoelectron spectroscopy (XPS), and thermogravimetric (TG) curves revealed the successful covalent functionalization of GO to rGO-COOH by significantly enhanced ―COOH groups in FTIR and increased peak area of carboxyl groups in XPS. A series of characterizations, including X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), XPS, and UV-Vis adsorption spectra, were performed to demonstrate the successful synthesis of TiO₂/rGO-COOH photocatalysts. The experimental data for the hydrogen-evolution rate showed that the TiO₂/rGO-COOH displayed an extremely high hydrogen-generation activity (254.2 μmol∙h⁻¹∙g⁻¹), which was 2.06- and 4.48-fold higher than those of TiO₂/GO and TiO₂, respectively. The enhanced photocatalytic activity of TiO₂/rGO-COOH is ascribed to the carboxyl groups of carboxyl-functionalized graphene, which act as effective hydrogen-generation active sites and enrich hydrogen ions owing to their excellent nucleophilicity that facilitates the interfacial hydrogen production reaction of TiO₂. This study provides novel insights into the development of high-activity graphene-supported photocatalysts in the hydrogen-generation field.      

微波辅助快速制备2D/1D ZnIn2S4/TiO2 S型异质结及其光催化制氢性能

The threat and global concern of energy crises have significantly increased over the last two decades. Because solar light and water are abundant on earth, photocatalytic hydrogen evolution through water splitting has been considered as a promising route to produce green energy. Therefore, semiconductor photocatalysts play a key role in transforming sunlight and water to hydrogen energy. To date, various photocatalysts have been studied. Among them, TiO₂ has been extensively investigated because of its non-toxicity, high chemical stability, controllable morphology, and high photocatalytic activity. In particular, 1D TiO₂ nanofibers (NFs) have attracted increasing attention as effective photocatalysts because of their unique 1D electron transfer pathway, high adsorption capacity, and high photoinduced electron–hole pair transfer capability. However, TiO₂ NFs are considered as an inefficient photocatalyst for the hydrogen evolution reaction (HER) because of their disadvantages such as a large band gap (~3.2 eV) and fast recombination of photoinduced electron–hole pairs. Therefore, the development of a high-performance TiO₂ NF photocatalyst is required for efficient solar light conversion. In recent years, several strategies have been explored to improve the photocatalytic activity of TiO₂ NFs, including coupling with narrow-bandgap semiconductors (such as ZnIn₂S₄). Recently, microwave (MW)-assisted synthesis has been considered as an important strategy for the preparation of photocatalyst semiconductors because of its low cost, environment-friendliness, simplicity, and high reaction rate. Herein, to overcome the above-mentioned limiting properties of TiO₂ NFs, we report a 2D/1D ZnIn₂S₄/TiO₂ S-scheme heterojunction synthesized through a microwave (MW)-assisted process. Herein, the 2D/1D ZnIn₂S₄/TiO₂ S-scheme heterojunction was constructed rapidly by using in situ 2D ZnIn₂S₄nanosheets decorated on 1D TiO₂ NFs. The loading of ZnIn₂S₄ nanoplates on the TiO₂ NFs could be easily controlled by adjusting the molar ratios of ZnIn₂S₄ precursors to TiO₂ NFs. The photocatalytic activity of the as-prepared samples for water splitting under simulated solar light irradiation was assessed. The experimental results showed that the photocatalytic performance of the ZnIn₂S₄/TiO₂ composites was significantly improved, and the obtained ZnIn₂S₄/TiO₂ composites showed increased optical absorption. Under optimal conditions, the highest HER rate of the ZT-0.5 (molar ratio of ZnIn₂S₄/TiO₂= 0.5) sample was 8774 μmol·g^-1·h^-1, which is considerably higher than those of pure TiO₂ NFs (3312 μmol·g^-1·h^-1) and ZnIn₂S₄nanoplates (3114 μmol·g^-1·h^-1) by factors of 2.7 and 2.8, respectively. Based on the experimental data and Mott-Schottky analysis, a possible mechanism for the formation of the S-scheme heterojunction between ZnIn₂S₄ and TiO₂ was proposed to interpret the enhanced HER activity of the ZnIn₂S₄/TiO₂heterojunctionphotocatalysts.      

磷酸根修饰的Mn掺杂介孔TiO2在VUV-PCO体系高效催化氧化甲苯性能

Vacuum ultraviolet irradiation coupled with photocatalytic oxidation (VUV-PCO) is an efficient and promising method for eliminating pollutants at room temperature; it involves three processes: vacuum ultraviolet (VUV) photolysis, photocatalytic oxidation (PCO), and ozone catalytic oxidation. Herein, toluene was chosen as the representative volatile organic compound (VOC), which is one of the most important precursors to form fine particulate matter and photochemical smog, because of its high toxicity and extensive existence in industries. All experiments were performed in a fixed-bed continuous-flow reactor that contained units for VUV photolysis and PCO. Mesoporous P-Mn-TiO₂ was prepared by one-step hydrolysis and used as a catalyst for the oxidation of gaseous toluene under VUV irradiation through the VUV-PCO process. The as-prepared P-Mn-TiO₂ samples were characterized by scanning electron microscope (SEM), transmission electron microscope (TEM), ultraviolet-visible light (UV-Vis) spectroscopy, and X-ray diffraction (XRD) analysis to determine the physicochemical properties of the catalysts and to determine the mechanisms of Mn doping and phosphoric acid modification and the effects of these processes on photocatalytic activity, ozone catalytic activity, and adsorption performance. The results indicated that the synergistic effect of phosphoric acid modification and Mn doping can improve the ozone catalytic activity and photocatalytic performance by increasing the number of oxygen active sites, completely eliminating the outlet ozone, and simultaneously promoting the efficient degradation of toluene. Moreover, doping TiO₂ with Mn³⁺ significantly enhanced light harvesting, and numerous oxygen vacancies can be generated on the catalyst surface because of the presence of doped Mn³⁺ in the lattice, which adsorbs and transforms the oxygen species for toluene degradation. In addition, modification with an appropriate amount of phosphate groups can facilitate O₂ and O₃ adsorption on the TiO₂ surface that can favor photo-induced charge carrier separation, thereby significantly improving the photocatalytic and ozone catalytic activities. The excellent catalytic performance of mesoporous P-Mn-TiO₂ for toluene degradation and outlet ozone elimination was ascribed to the formation of highly reactive oxidizing species such as O(1D), O(3P), and ·OH via the catalytic decomposition of O₃ adsorbed on the oxygen vacancy sites containing Mn and phosphate groups on the catalyst surface. In the VUV-PCO process, toluene was first destructed via VUV photolysis and oxidized by residual O₃ generated from VUV photolysis and the active oxygen species formed in the presence of the catalyst. Finally, toluene and the generated intermediate products were oxidized and degraded to CO₂ and H₂O through VUV-PCO. In addition, the outlet ozone byproduct was simultaneously eliminated by the multifunctional catalyst.      

介孔TiO2对溶菌酶吸附的动力学和热力学

773.15 K下焙烧二钛酸(H₂Ti₂0₅)制备了介孔结构TiO₂。采用比表面分析仪(BET)、扫描电镜(SEM)、拉曼(Raman)光谱和X射线衍射(XRD)仪进行表征研究了介孔TiO₂对溶菌酶的吸附行为和机理。结果表明,该吸附过程较好地满足Langmuir吸附模型;随着溶液pH值的增高,溶菌酶在介孔TiO₂上的吸附量先增大后减小。在pH = 7.2时,达到最大吸附容量72.5 mg·g^-1。该介孔TiO₂对溶菌酶具有良好的吸附稳定性,经过5次循环后吸附的溶菌酶残余量仍有81.6%。动力学研究表明,介孔TiO₂与溶菌酶间的吸附满足准二级动力学模型,吸附传质过程由膜扩散和粒内扩散共同影响与控制。对热力学参数的计算发现,该过程ΔG⁰ < 0, ΔH⁰ > 0, ΔS⁰ > 0,表明介孔TiO₂对溶菌酶的吸附是一个自发的、吸热的熵增过程。     

The photocatalytic activity of TiO2 foam and surface modified binary oxide titania nanoparticles

Surface modified titania dioxide composite nanoparticles prepared by hydrogen reduction reaction and a mesoporous TiO₂ foam made from a surface modifier and a long chain organic surfactant were characterized by diffractive, spectroscopic and microscopic techniques and studied for their catalytic activity towards the decomposition of an industrial water pollutant, methyl orange. The surface deposition of ruthenium and silicon particles improved the photocatalytic activity of the composite particles resulting in a faster decomposition of the methyl orange compared to commercial TiO₂ alone. Modification of TiO₂ with RuO₂ only offered a marginal benefit over TiO₂ while the incorporation of RuO₂ and SiO₂ into TiO₂ resulted in a marked increase in the rate constant and catalytic activity. These results are consistent with the enhanced surface properties of the composite materials resulting from the modification of TiO₂ with RuO₂ and SiO_2. This surface enhancement effects appear synergetic to the charge separation process and hence the photocatalytic results are explained on the basis of a mechanism involving efficient charge transfer across the interfaces of the composites involving photogenerated electron–hole pairs. Results obtained in this study show that the percentage degradation after 1 h of illumination was 47.15% for TiO₂ foam, 75.5 and 106.4%, respectively, for TiO₂/RuO₂ (SiO₂ 5%, w/w) and TiO₂/RuO₂(SiO₂ 10%, w/w) and 34.15% for commercial TiO₂.     

钾对CuSO4/TiO2脱硝催化剂的失活效应(英文)

为了减少碳排放，在世界各地兴建了越来越多的生物质电厂。钾元素是生物质电厂烟气中的一种典型元素并且可以引起脱硝催化剂的失活。具有优异抗SO₂性能的CuSO₄/TiO₂催化剂被认为是一种有前景的非钒基脱硝催化剂。但是，钾对CuSO₄/TiO₂催化剂的影响仍不清楚。本文研究了钾对CuSO₄/TiO₂催化剂的影响并且与商业V₂O₅-WO₃/TiO₂ (VWTi)催化剂作了比较，采用多种表征方法对催化剂样品进行了表征。钾可以引起CuSO₄/TiO₂和VWTi催化剂的失活，但是CuSO₄/TiO₂催化剂对钾的抵抗能力明显高于商业VWTi催化剂。钾会与CuSO₄/TiO₂催化剂中的CuSO₄发生反应生成CuO和...