硼掺杂SiC的制备、表征及其可见光分解水产氢性能(英文)

采用原位碳热还原法制备了硼掺杂的β-SiC(Bx SiC)光催化剂,并考察了其可见光下光催化分解水制氢的性能.利用X射线衍射仪、X射线光电子能谱、扫描电镜及紫外-可见吸收光谱等测试方法对所制备催化剂的晶型、形貌、表面性质及能带结构进行了表征.分析结果表明,硼原子掺杂进入SiC晶格并取代了Si位点,在价带上方形成了浅受主能级,从而导致了带隙宽变窄.浅受主能级作为空穴的捕获中心可抑制光生电子和空穴的复合.因此,与SiC相比,硼掺杂SiC光催化剂在可见光下催化分解水产氢的活性大大提高.当B/Si的摩尔比为0.05时,硼掺杂SiC表现出最高的光催化产氢活性.     

钯氮共掺杂TiO2的制备与表征及其可见光催化活性

在空气气氛和N₂中热处理表面均匀分散有尿素和氯化钯的纳米管钛酸,制备了两个系列Pd/N共掺杂的TiO₂光催化剂,并对所得样品进行了X射线衍射、透射电镜、X射线光电子能谱、紫外-可见漫反射光谱、荧光光谱和电子自旋共振等表征.结果表明,焙烧气氛对样品的形貌、晶体结构、光谱吸收、生成的氧空位浓度和可见光光催化性能的影响很大,其中在空气气氛中制备的样品光催化性能优于在N₂中制备的样品.在可见光(λ≥420nm)照射下,以丙烯为模型污染物考察了样品的光催化活性,发现在空气中400℃下焙烧的样品具有最佳的可见光催化活性.另外,讨论了Pd/N共掺杂TiO₂光催化剂具有可见光响应的机理,认为掺杂的Pd/N元素和制备过程中生成的氧空位是影响可见光催化性能的重要因素.     

Ln掺杂BiVO4(Ln=Eu、Gd、Er)光催化剂的制备和活性研究

采用水热合成法, 制备出Eu、Gd和Er掺杂的BiVO₄复合光催化剂,并采用X射线衍射、X射线光电子谱、扫描电子显微镜和紫外-可见漫反射光谱技术对其进行分析表征。通过可见光下降解水溶液中甲基橙分子来考察其光催化性能,结果显示掺杂的复合光催化剂活性都强于纯的BiVO₄,对掺杂复合光催化剂的催化活性增强机理进行了讨论和描述。     

硼掺杂碳化硅负载Pt催化剂的甲醇电催化氧化性能

以硼掺杂碳化硅(B0.1SiC)为载体,采用循环伏安法在B0.1SiC载体上电沉积Pt纳米粒子制备了Pt/B0.1SiC催化剂。利用X射线光电子能谱、X射线衍射、氮气吸附-脱附、扫描电镜及透射电镜等测试方法对催化剂的晶型、表面性质及形貌进行了表征。结果表明,硼原子掺杂进入SiC晶格并取代了Si位点,使B0.1SiC载体的导电性增强;Pt纳米粒子均匀地分布在B0.1SiC载体上,平均粒径为2.7 nm。与相同条件下制备的Pt/SiC催化剂相比,Pt/B0.1SiC具有较大的电化学活性表面积、更高的甲醇催化氧化活性和稳定性。     

氟掺杂TiO2纳米管的可见光催化活性及第一性原理计算

作为光催化技术的核心, 提高TiO₂的光催化活性和对可见光的利用率是当前光催化研究中最重要的研究课题. 为了提高TiO₂纳米管的可见光催化活性, 采用化学气相沉积法对TiO₂纳米管进行了氟掺杂. 扫描电子显微镜(SEM)结果表明退火温度对于TiO₂纳米管的形貌完整性有较大影响, 当样品在550和700 °C下退火, 氟掺杂TiO₂纳米管结构受损; X射线衍射(XRD)分析表明氟掺杂对TiO₂由锐钛矿相转化为金红石相有阻碍作用; X射线光电子能谱(XPS)测试表明化学气相沉积能有效地对TiO₂纳米管进行非金属掺杂, 且该方法安全、操作简单. 氟掺杂TiO₂纳米管对甲基橙有较高的可见光催化降解活性. 第一性原理计算结果表明氟掺杂对TiO₂带隙无显著影响, 费米能级附近的F 2p轨道电子位于价带底部, 与O 2p交联作用较小, 因此对TiO₂光吸收带边影响不大. 氟掺杂能促进表面氧空穴的产生, 增加表面酸度与Ti³⁺, 有利于减少电子-空穴复合率, 从而提高其光催化活性.     

C-N共掺杂纳米TiO2的制备及其光催化制氢活性

采用TiCN粉末在空气气氛中不同温度下焙烧制得C-N共掺杂的纳米TiO2光催化剂. 利用X射线衍射(XRD)、透射电镜(TEM)、紫外-可见漫反射光谱(UV-Vis DRS)以及X射线光电子能谱(XPS)等手段对其进行了表征. XRD和XPS结果表明, TiCN中的C和N元素可以被O取代得到C-N共掺杂的TiO2. DRS结果表明, 所制得的C-N共掺杂的TiO2在可见光区域比P25表现出更强的光吸收性能. 以Na2S-Na2SO3体系为牺牲剂, 分别考察了不同温度下焙烧得到的C-N共掺杂的TiO2光催化分解水产氢的活性. 结果表明, 550 ℃焙烧得到的C-N共掺杂的TiO2在紫外光照射下具有最高的光解水产氢活性,产氢速率为41.1 μmol·h-1, 大于P25的光解水产氢活性(26.2 μmol·h-1). 在紫外-可见光照射下, 光解水产氢速率仅为0.2 μmol·h-1, 这可能是由于C-N掺杂引起的可见光范围的吸收对光催化分解水产氢活性的贡献较小.     

Ce掺杂K2La2Ti3O10催化剂的可见光高效催化制氢的研究

采用高温固相法合成了铈掺杂的K₂La₂Ti₃O₁₀催化剂, 利用X射线衍射(XRD)、紫外-可见漫反射(UV-vis DRS)、透射电镜(TEM)和X射线光电子能谱(XPS)对催化剂进行了表征. 考察了催化剂的可见光催化分解甲醇水溶液制氢的活性, 并对可见光催化机理进行了分析. 研究表明, 铈的掺杂没有改变K₂La₂Ti₃O₁₀的微晶结构, 并使催化剂粒径有所减小. 紫外可见漫反射分析表明禁带宽度为2.3 eV左右, 对可见光具有较高吸收. XPS表明La和Ti为＋3和＋4价, 而Ce则是＋3和＋4的混合价态. 担载2 wt% Pt后, 在可见光下光催化活性大大提高, 当铈的掺杂量为0.5 mol%(即Ce取代La的摩尔百分量)时, 光催化活性达到最大, 产氢速率为0.05 mmol/h; 光照5 h后产氢量为0.22 mmol, 而纯K₂La₂Ti₃O₁₀的产氢量只有0.037 mmol.     

两步水热法合成Sn_2Nb_2O_7纳米晶及其高效可见光分解水制氢性能（英文）

铌基半导体光催化材料因其具有独特的晶体结构和能带结构在光催化分解水制氢领域受到科研工作者的高度关注.然而,大多数铌基半导体光催化剂仅能够在紫外光驱动下实现光催化分解水制氢,具有可见光响应的铌基半导体光催化剂不仅数量少而且活性较低,因此发展新型纳米铌基半导体光催化剂并实现其高效可见光催化分解水产氢具有重要的学术和实用意义.具有烧绿石构型的Sn_2Nb_2O_7材料由于具有较窄的禁带宽度(2.4 e V)和合适的导带和价带电势在可见光催化分解水制氢方面引起了科研人员广泛的兴趣.然而,目前报道的利用高温固相法制备的块体Sn_2Nb_2O_7材料由于颗粒尺寸较大和比表面积较小而导致光催化活性较差.因此,发展一种简便高效的制备方法实现纳米Sn_2Nb_2O_7材料的可控制备进而提高其可见光催化活性仍具有一定的挑战性.我们发展了一种简便的两步水热合成方法实现了Sn_2Nb_2O_7纳米晶的可控制备.扫描电镜和透射电镜测试结果表明,通过两步水热法得到的Sn_2Nb_2O_7纳米颗粒具有较好分散度,其平均颗粒尺寸为20 nm.X射线衍射测试结果也进一步证明,通过两步水热法可以实现Sn_2Nb_2O_7纳米晶的可控制备.比表面积测试结果表明,Sn_2Nb_2O_7纳米晶的比表面积约为52.2 m~2/g,远远大于固相法制备的块体Sn_2Nb_2O_7材料(2.3 m~2/g).大量研究表明,大的比表面积有利于半导体催化材料催化活性的提升.通过考查所制备的Sn_2Nb_2O_7纳米晶的可见光分解水制氢能力,对其催化性能进行了评价.研究结果表明,以乳酸为空穴消耗剂,负载0.3wt.%Pt纳米颗粒作为助催化剂的Sn_2Nb_2O_7纳米晶表现出优异的可见光催化分解水产氢性能,其产氢速率是块体Sn_2Nb_2O_7材料的5.5倍.Sn_2Nb_2O_7纳米晶可见光催化分解水产氢性能提高的主要原因是其具有高分散度的纳米颗粒、较大的比表面积和更正的价带电势.首先,颗粒尺寸的纳米化能够显著减小光生电子和空穴的迁移距离,实现光生载流子快速迁移到催化剂表面进而参与催化反应;其次,大的比表面积能够提供更多的催化活性位点,进而有利于催化活性的提高;最后,X射线光电子能谱测试表明,Sn_2Nb_2O_7纳米晶具有更正的价带电势,研究表明,价带电势越正,其光生空穴氧化能力越强.在光催化分解水制氢过程中,具有较强氧化能力的光生空穴通过与空穴牺牲剂乳酸快速反应而被消耗掉,抑制了光生电子与空穴的复合,进而导致其具有较高的光催化产氢活性.     

Cu掺杂TiO2纳米管可见光催化矿化甲苯

采用低温水热法制备氢钛酸管, 通过吸附-煅烧法制备Cu掺杂TiO₂纳米管(Cu-TNT)催化剂. 利用X射线衍射(XRD)、电感耦合等离子体-原子发射光谱(ICP-AES)、X射线光电子能谱(XPS)、透射电镜(TEM)、紫外-可见漫反射光谱(UV-Vis-DRS)和电化学测试手段对样品进行表征, 并进行平面波赝势密度泛函理论(DFT)计算. 结果表明, 样品中Cu/Ti原子比接近理论值, Cu掺杂进入TiO₂晶格内部, 诱发催化剂可见光活性. 掺Cu后,Cu 3d轨道和O 2p轨道杂化形成价带顶, 价带负向偏移, 样品禁带宽度减小为2.50-2.91 eV, 具有可见光响应.以甲苯为模型污染物研究催化剂对挥发性有机化合物(VOCs)的催化去除和矿化效果. 未掺杂的TNT可见光催化活性较差; Cu掺杂量超过0.1%(Cu/Ti原子比)时, 样品催化活性也减弱; Cu掺杂量为0.1%的催化剂具有最佳可见光催化氧化能力, 7 h内甲苯的去除率达77%, 甲苯的矿化率达59%.     

硼硫共掺杂TiO2的光催化性能及掺杂机理

采用水热法制备了硼硫共掺杂的TiO2光催化剂(TiO2-B-S),并用其光催化降解甲基橙.结果表明,在240℃下水热反应12h时制得的TiO2-B-S具有较高的催化活性,紫外光照射50min和太阳光照射230min时对甲基橙的降解率分别达99.8%和81%.X射线粉末衍射、紫外-可见漫反射光谱和X射线光电子能谱等研究表明,TiO2-B-S为锐钛矿晶型,硫硼掺杂能抑制TiO2粒径的生长;TiO2-B-S同时具有较高的紫外光和可见光活性的原因可能是掺杂的硼以B3 进入晶格中,导致TiO2晶格畸变,带隙变窄.掺杂的硼和硫还提高了TiO2的表面酸度和对可见光的吸收.     

B离子掺杂TiO2催化剂(TiO2－xBx)光催化活性的研究

采用溶胶-凝胶法制备出纳米TiO₂和TiO_2－xB_x催化剂. 光催化实验证明, TiO_2－xB_x催化剂的紫外、可见光催化活性均高于TiO₂. XRD, XPS和Raman结果表明, B离子是以取代式掺杂占据了TiO₂的O^2－的晶格位置. UV-Vis和PL谱的结果表明, B离子的2p轨道与O的2p轨道形成混合价带, 产生可见光响应, B离子的掺入有效地阻止了光生载流子的复合, 促进了其分离, 是TiO_2－xB_x催化剂紫外、可见光催化活性提高的主要原因.     

Engineering Graphdiyne for Solar Photocatalysis

Graphdiyne (GDY) with a direct band gap, excellent carrier mobility and uniform pores, is regarded as a promising photocatalytic material for solar energy conversion, while the research on GDY in photocatalysis is a less developed field. Herein, the distinctive structure, adjustable band gap, and electronic properties of GDY for photocatalysis is firstly summarized. The construction and progress of GDY-based photocatalysts for solar energy conversion, including H₂ evolution reaction (HER), CO₂ reduction reaction (CO₂RR) and N₂ reduction reaction (NRR) are then elaborated. At last, the challenges and perspectives in developing GDY-based photocatalysts for solar fuel production are discussed. It is anticipated that a timely Minireview will be helpful for rapid progress of GDY in solar energy conversion.     

Enhanced sunlight-driven photocatalytic performance of Bi-doped CdMoO4 benefited from efficient separation of photogenerated charge pairs

In this paper, to further boost the photocatalytic performance of CdMoO₄, Bi³⁺ was successfully doped into CdMoO₄ by a facile microwave hydrothermal method. The Bi-doped CdMoO₄ photocatalysts prepared were characterized by Brunauer-Emmett-Teller (BET) method, X-ray diffraction (XRD), UV–Vis diffuse reflectance spectroscopy (DRS), scanning electron microscopy (SEM), energy dispersive spectrometer (EDS), high-resolution transmission electron microscopy (HRTEM), X-ray photoelectron spectroscopy (XPS), electron spin-resonance (ESR) and surface photovoltage spectroscopy (SPS). The results exhibit that doping Bi³⁺ into CdMoO₄ remarkably boosts the separation rate of photoinduced charge pairs and the specific surface area, decrease the crystal size, narrows the band gap of the CdMoO₄ and induces the binding energy shift of Cd, all these advantageous factors result in the promoted photocatalytic performance of CdMoO₄. Using rhodamine B (RhB) as model toxic pollutant, the photocatalytic activities of the photocatalysts were evaluated under a 500 W Xe lamp irradiation. When the molar ratio of Bi/Cd is 0.2%, Bi-CdMoO₄ prepared displays the best photocatalytic performance, the photocatalytic performance of the 0.2% sample is more than twice of that of the reference CdMoO₄.     

Fabrication and photocatalytic activities of SrTiO3 nanofibers by sol–gel assisted electrospinning

SrTiO₃ nanofibers were successfully prepared by a facile electrospinning method with subsequent calcination in air. These one dimensional nanostructures were characterized for the morphological, structural and optical properties by scanning electron microscopy, transmission electron microscopy, X-ray diffraction, X-ray photoelectron spectroscopy and UV–visible diffuse reflectance spectroscopy. The photocatalytic investigations showed that the SrTiO₃ nanofibers possessed enhanced photocatalytic efficiency in photodegradation of rhodamine B and photocatalytic H₂ evolution from water splitting under ultraviolet light irradiation, compared with the SrTiO₃ nanoparticles and P25. The enhanced photocatalytic performance can be ascribed to the beneficial microstructure and more negative conduction band edge compared with P25.     

Realizing high hydrogen evolution activity under visible light using narrow band gap organic photocatalysts

The design and synthesis of conjugated semiconducting polymers for photocatalytic hydrogen evolution have engendered intense recent interest. However, most reported organic polymer photocatalysts show a relatively broad band gap with weak light absorption ability in the visible light region, which commonly leads to a low photocatalytic activity under visible light. Herein, we synthesize three novel dithieno[3,2-b:2′,3′-d]thiophene-S,S-dioxide (DTDO) containing conjugated polymer photocatalysts by a facile C–H arylation coupling polymerization reaction. The resulting polymers show a broad visible light absorption range up to 700 nm and a narrow band gap down to 1.81 eV due to the introduction of the DTDO unit. Benefiting from the donor–acceptor polymer structure and the high content of the DTDO unit, the three-dimensional polymer PyDTDO-3 without the addition of a Pt co-catalyst shows an attractive photocatalytic hydrogen evolution rate of 16.32 mmol h⁻¹ g⁻¹ under visible light irradiation, which is much higher than that of most reported organic polymer photocatalysts under visible light.

Narrow band gap conjugated polymer photocatalysts containing dithieno[3,2-b:2′,3′-d]thiophene-S,S-dioxide show an attractive photocatalytic hydrogen evolution rate of 16.32 mmol h⁻¹ g⁻¹ under visible light irradiation.     

Carbon-based H2-production photocatalytic materials

Photocatalytic hydrogen production from water splitting is of promising potential to resolve the energy shortage and environmental concerns. During the past decade, carbon materials have shown great ability to enhance the photocatalytic hydrogen-production performance of semiconductor photocatalysts. This review provides a comprehensive overview of carbon materials such as CNTs, graphene, C₆₀, carbon quantum dots, carbon fibers, activated carbon, carbon black, etc. in enhancing the performance of semiconductor photocatalysts for H₂ production from photocatalytic water splitting. The roles of carbon materials including supporting material, increasing adsorption and active sites, electron acceptor and transport channel, cocatalyst, photosensitization, photocatalyst, band gap narrowing effect are explicated in detail. Also, strategies for improving the photocatalytic hydrogen-production efficiency of carbon-based photocatalytic materials are discussed in terms of surface chemical functionalization of the carbon materials, doping effect of the carbon materials and interface engineering between semiconductors and carbon materials. Finally, the concluding remarks and the current challenges are highlighted with some perspectives for the future development of carbon-based photocatalytic materials.     

One-pot hydrothermal synthesis of willow branch-shaped MoS2/CdS heterojunctions for photocatalytic H2 production under visible light irradiation

Willow branch-shaped MoS₂/CdS heterojunctions are successfully synthesized for the first time by a facile one-pot hydrothermal method. The as-prepared samples were characterized by X-ray diffraction, X-ray photoelectron spectroscopy, scanning electron microscopy, transmission electron microscopy, nitrogen adsorption-desorption measurements, diffuse reflectance spectroscopy, and photoelectrochemical and photoluminescence spectroscopy tests. The photocatalytic hydrogen evolution activities of the samples were evaluated under visible light irradiation. The resulting MoS₂/CdS heterojunctions exhibit a much improved photocatalytic hydrogen evolution activity than that obtained with CdS and MoS₂. In particular, the optimized MC-5 (5 at.% MoS₂/CdS) photocatalyst achieved the highest hydrogen production rate of 250.8 μmol h^-1, which is 28 times higher than that of pristine CdS. The apparent quantum efficiency (AQE) at 420 nm was 3.66%. Further detailed characterizations revealed that the enhanced photocatalytic activity of the MoS₂/CdS heterojunctions could be attributed to the efficient transfer and separation of photogenerated charge carriers resulting from the core-shell structure and the close contact between MoS₂ nanosheets and CdS single-crystal nanorods, as well as to increased visible light absorption. A tentative mechanism for photocatalytic H₂ evolution by MoS₂/CdS heterojunctions was proposed. This work will open up new opportunities for developing more efficient photocatalysts for water splitting.     

Photocatalytic performance of BiFeO3 based on MOFs precursor

BiFeO₃ (BFO) is considered to be a potential visible light photocatalytic material for organic degradation due to its narrow band gap. In this work, the BFO with smaller band gap and better photocatalytic performance was prepared by thermal decomposition of we prepared smaller band gap and better photocatalytic performance BFO by thermal decomposition of MOFs precursor Bi[Fe (CN)₆]·5H₂O. Among them, BFO‐0.5 has the best photocatalytic activity, which the photocatalytic degradation rate of methyl orange (MO) aqueous solution is 98.1% within 60 minutes. The photocatalytic activity is almost unchanged after four cycles of use. The enhanced photocatalytic activity of BFO could be attributed to the enhanced optical absorption and smaller particles. It may be conducive to design more efficient photocatalysts for photocatalytic degradation of organic dyes.     

Nanoplasmonic zirconium nitride photocatalyst for direct overall water splitting

The ability of plasmonic nanostructures to efficiently harvest light energy and generate energetic hot carriers makes them promising materials for utilization in photocatalytic water spitting.Apart from the traditional Au and Ag based plasmonic photocatalysts,more recently the noble-metal-free alternative plasmonic materials have attracted ever-increasing interest.Here we report the first use of plasmonic zirconium nitride（ZrN） nanoparticles as a promising photocatalyst for water splitting.Highl...     

Enhancement of the photocatalytic activity of modified TiO2 nanoparticles with Zn2+. correlation between structure and properties

Zinc-doped and undoped TiO₂ photocatalysts were synthesized via sol-gel techniques. Doping of TiO₂ with M²⁺ (M-Zn) was intended to create tail states within the band gap of TiO2. These can subsequently be employed as efficient photocatalysts which can effectively decompose organic contaminants only with visible light activation. The structure, physico-chemical and optical properties of the products were characterized by using the X-ray diffraction (XRD), Raman spectra, UV-vis diffuse reflectance spectroscopy (DRS) and electrochemical impedance spectroscopy (EIS) techniques. Doping shifts the optical absorption edge to the visible region and decreases the charge-transfer resistance. Under visible light, the composite nanoparticles very efficiently catalyze the MB dye. Results implied that Zn doping increased photoinduced charge transfer rate, and the use of described methods is a powerful tool toward predicting and understanding the photocatalytic processes and behaviors.