Ni2P-NiS双助剂促进g-C3N4光催化产氢动力学

本文通过简单的一步水热法得到Ni₂P-NiS双助催化剂,之后采用溶剂蒸发法将Ni₂P-NiS与g-C₃N₄纳米片结合构建获得无贵金属的Ni₂P-NiS/g-C₃N₄异质结。研究结果表明,优化后的复合材料具有良好的光催化产氢活性,其产氢速率最高可到6892.7 μmol·g^-1·h^-1,分别为g-C₃N₄ (150 μmol·g^-1·h^-1)、15%NiS/g-C₃N₄ (914.5 μmol·g^-1·h^-1)和15%Ni₂P/g-C₃N₄ (1565.9 μmol·g^-1·h^-1)的46.1、7.5和4.4倍。这主要归因于Ni₂P-NiS相比Ni₂P和NiS单体具有更好的载流子转移能力,其与g-C₃N₄形成的肖特基势垒能有效促进光生载流子在二者界面上的分离,同时Ni₂P-NiS能进一步降低析氢过电势,进而显著增强了表面析氢反应动力学。本研究为开发稳定、高效的非贵金属产氢助剂提供了实验基础。     

一维/二维W18O49/多孔g-C3N4梯形异质结构建及其光催化析氢性能研究

提高光催化分解水制氢的效率是能量转换领域的关键挑战。本研究首先合成了二维多孔氮化碳(PCN),然后在二维PCN上原位生长了一维W₁₈O₄₉ (WO),形成了一种新型的梯形(S型)异质结。该异质结可以加快界面电荷的分离和转移,赋予WO/PCN体系更好的氧化还原能力。此外,具有多孔结构的PCN提供了更多的催化活性位点。与WO和PCN相比,20% WO/PCN复合材料具有更高的H₂产率(1700 μmol·g^-1·h^-1),是PCN (30 μmol·g^-1·h^-1)的56倍。本研究提供了一种新S型光催化剂用于光催化制氢领域。     

Nd2O3/TiO2光催化剂的光生羟基自由基和光活性

以硝酸钕和钛酸四正丁酯作为前驱体,采用溶胶-凝胶法制备了Nd₂O₃/TiO₂纳米光催化剂,并通过XRD和BET等手段进行了表征.以对苯二甲酸作为探针分子,结合化学荧光技术研究了光催化剂表面羟基自由基的生成;并以甲基橙为光催化降解反应模型化合物,考察了光催化剂的活性.测定了甲基橙在TiO₂和Nd₂O₃/TiO₂(1.0%)光催化剂上的吸附常数.结果表明:Nd₂O₃掺杂使TiO₂的粒径减小,比表面积增大;羟基自由基的生成速率越大,催化剂的催化活性越高.Nd₂O₃掺杂有利于反应底物在催化剂表面的吸附,Nd₂O₃的最佳掺入量为Nd/Ti(摩尔比)=1.0%.     

In2O3修饰三维纳米花MoSx构建S型异质结用于高效光催化产氢

形貌控制和异质结构建是提升光催化剂性能的有效策略。本文采用In₂O₃修饰三维纳米花MoS_x并构建S型异质结,为电子的传输提供了特殊的转移途径。通过合理调控In₂O₃的负载量,MoS_x/In₂O₃的最佳产氢速率能够达到6704.2 μmol∙g⁻¹∙h⁻¹,是纯MoS_x的1.8倍。采用荧光光谱和电化学测试证实复合材料中内部电子和空穴对的分离效率得到了有效的提升,并利用紫外漫反射测试和羟基自由基实验推测了析氢机理。     

富含光诱导氧空位Bi12O17Br2的制备及其高效光催化固氮性能(英文)

采用一步水热法制备了Bi₁₂O₁₇Br₂光催化剂,其平均微片尺寸为1.2μm,比表面积约为29 m²·g^-1。Bi₁₂O₁₇Br₂的禁带宽度为2.42 eV,能够响应可见光。值得注意的是,在光照条件下Bi₁₂O₁₇Br₂表面能够产生氧空位;光诱导氧空位不仅能促进氮气在催化剂表面的吸附,而且对吸附的氮气分子的活化起到至关重要的作用。实验结果表明在可见光照射下,Bi₁₂O₁₇Br₂光催化剂上的氨生成速率为337.6μmol·g^-1·h^-1。在可见光的驱动下,Bi₁₂O₁₇Br₂光催化剂能够实现氮气与水反应生成氨的过程。     

反蛋白石结构ZnO@PDA用于增强光催化产H2O2性能

利用太阳能驱动生产高能量密度的H₂O₂太阳能燃料引起了广泛关注,但目前光催化剂缓慢的动力学限制了其实际应用。本文制备一种聚多巴胺(PDA)改性的反蛋白石结构ZnO(ZnO@PDA)光催化剂,用于可持续性的光催化产H₂O₂。由于电子的转移,因此当PDA与ZnO接触后,会在界面处形成一个从PDA指向ZnO的内建电场。在内建电场和能带弯曲的驱动下,ZnO导带中的光生电子与PDA最高占据分子轨道(HOMO)中的空穴复合,符合梯型异质结的电荷转移和分离途径。这种独特的梯型异质结确保了有效的电子或空穴的分离并且留存下具有强氧化还原能力的光生载流子。此外,与纯ZnO相比,反蛋白石结构的ZnO@PDA具有更强的光吸收能力。实验表明,归因于光吸收能力的提高,光生载流子的有效分离和强氧化还原能力,负载0.03% (原子分数) PDA的ZnO样品具有最佳的产H₂O₂性能(1011.4 μmol·L^-1·h^-1),分别是纯ZnO和PDA的4.4和8.9倍。     

B,N-SnO2/TiO2光催化剂的制备及其光催化性能研究

为了提高TiO₂在可见光下的光催化活性, 采用聚合物前驱体法制备了B,N共掺杂的SnO₂/TiO₂(B,N-SnO₂/TiO₂)粉体型光催化剂. 进一步为了提高光催化剂的实用性, 通过浸渍-裂解法制备了氧化铝纤维毡负载的B,N-SnO₂/TiO₂光催化剂. 利用X射线衍射仪、场发射扫描电子显微镜、场发射透射电子显微镜、X射线光电子能谱、比表面积分析仪、紫外-可见分光光度计等对其进行了表征. 以氧氟沙星水溶液为模拟污染物, 考察了B,N-SnO₂/TiO₂粉体型光催化剂和负载型光催化剂的可见光催化活性及稳定性. 结果表明, 该粉体型光催化剂在可见光下光照15 min, 对氧氟沙星的降解率可达98.3%. 负载型光催化剂也表现出了良好的光催化性能及可重复性和稳定性, 在21次重复使用后光催化性能几乎不发生变化.     

MIL-125(Ti)衍生介孔圆盘状N-TiO2高效光催化降解气态苯(英文)

挥发性有机污染物(VOCs)对人或动物的危害较大,具有致癌、致畸和致突变性.气固相光催化法已经成为一种具有广阔应用前景的VOCs治理技术.传统半导体光催化剂TiO₂带隙较宽(E_g=3.2 eV),太阳光利用效率低.特别是对光催化降解VOCs而言,反应过程中产生的含碳类中间产物易在TiO₂表面积累,致使其失活.因此,如何拓宽TiO₂的光谱响应范围,提高光量子效率及其在VOCs氧化过程中的循环利用性一直是研究重点.由于O和N具有类似的化学结构和电子特征,对TiO₂进行N掺杂(N-TiO₂)是实现TiO₂可见光催化的有效途径.TiO₂前驱体和氮源的种类对N-TiO₂的带隙、N掺杂位点、N掺杂量、形貌和孔径影响较大.金属-有机骨架(MOFs)具有结构多样且可调、多孔性、比表面积大等优点,是制备特定形貌和结构的光催化材料的理想自牺牲模板.同时,有机配体易于在高温煅烧过程中从MOFs骨架中释放,其衍生物...     

Fe2O3-TiO2磁性复合材料的制备及可见光催化性能

以FeCl₃和Ti(C₄H₉O)₄为前驱体, 通过复合溶胶法制备了Fe₂O₃-TiO₂磁性复合光催化剂, 并用 XPS, XRD, SEM, EDS及BET进行了表征. 对亚甲基蓝的降解实验证明, Fe₂O₃的引入将复合材料的光响应范围扩展至可见光区, 且掺杂的Fe₂O₃摩尔分数为1.0%时, 样品可见光催化性能最高. 磁强计的测试结果显示, 复合光催化剂具有一定的磁性, 可在反应结束后利用磁场从体系分离, 使催化剂得到回收再利用.     

碳掺氧缺型TiO2纤维的无外碳源制备及光催化性能

采用溶胶-凝胶法, 结合离心纺丝技术及水蒸气活化工艺制备了一种碳掺氧缺型TiO₂(C-TiO_2-n)纤维光催化剂. 探究了C-TiO_2-n纤维的结构、 组分、 性质及碳掺杂对其光催化活性的影响. 结果表明, 在无外碳源引入的情况下, 利用TiO₂前驱体中的有机组分作为碳源, 可以实现对TiO₂的碳掺杂, 且碳掺杂明显改善了光催化剂的光捕获能力并有效抑制了光生载流子的复合. 在以水中偶氮染料活性艳红(X-3B)作为目标污染物的光催化降解实验中, C-TiO_2-n纤维展现了优良的光催化活性和循环稳定性. 在可见光照射60 min后, 其对X-3B的降解率达到96.99%, 动力学常数为0.0556 min^-1, 是氧缺型TiO₂纤维的19.86倍.     

Sc2MgGa2 and Y2MgGa2

Scandium magnesium gallide, Sc₂MgGa₂, and yttrium magnesium gallide, Y₂MgGa₂, were synthesized from the corresponding elements by heating under an argon atmosphere in an induction furnace. These intermetallic compounds crystallize in the tetragonal Mo₂FeB₂‐type structure. All three crystallographically unique atoms occupy special positions and the site symmetries of (Sc/Y, Ga) and Mg are m2m and 4/m, respectively. The coordinations around Sc/Y, Mg and Ga are pentagonal (Sc/Y), tetragonal (Mg) and triangular (Ga) prisms, with four (Mg) or three (Ga) additional capping atoms leading to the coordination numbers [10], [8+4] and [6+3], respectively. The crystal structure of Sc₂MgGa₂ was determined from single‐crystal diffraction intensities and the isostructural Y₂MgGa₂ was identified from powder diffraction data.     

Zur Kenntnis der Dialkalimetalldichalkogenide β-Na2S2, K2S2, α-Rb2S2, β-Rb2S2, K2Se2, Rb2Se2, α-K2Te2, β-K2Te2 und Rb2Te2

On Dialkali Metal Dichalcogenides β-Na₂S₂, K₂S₂, α-Rb₂S₂, β-Rb₂S₂, K₂Se₂, Rb₂Se₂, α-K₂Te₂, β-K₂Te₂ and Rb₂Te₂ The first presentation of pure samples of α- and β-Rb₂S₂, α- and β-K₂Te₂, and Rb₂Te₂ is described. Using single crystals of K₂S₂ and K₂Se₂, received by ammonothermal synthesis, the structure of the Na₂O₂ type and by using single crystals of β-Na₂S₂ and β-K₂Te₂ the Li₂O₂ type structure will be refined. By combined investigations with temperature-dependent Guinier-, neutron diffraction-, thermal analysis, and Raman-spectroscopy the nature of the monotropic phase transition from the Na₂O₂ type to the Li₂O₂ type will be explained by means of the examples α-/β-Na₂S₂ and α-/β-K₂Te₂. A further case of dimorphic condition as well as the monotropic phase transition of α- and β-Rb₂S₂ is presented. The existing areas of the structure fields of the dialkali metal dichalcogenides are limited by the model of the polar covalence.     

Crystal Structures of [Bu2Sn(O2PPh2)2], [Ph2Sn(O2PPh2)2], and [PhClSn(O2PPh2)OMe]2. Raman Spectra of [Ph2Sn(O2PPh2)2] and [PhClSn(O2PPh2)OMe]2

[(n‐Bu)₂Sn(O₂PPh₂)₂] ( 1 ), and [Ph₂Sn(O₂PPh₂)₂] ( 2 ) have been synthesized by the reactions of R₂SnCl₂ (R=n‐Bu, Ph) with HO₂PPh₂ in Methanol. From the reaction of Ph₂SnCl₂ with diphenylphosphinic acid a third product [PhClSn(O₂PPh₂)OMe]₂ ( 3 ) could be isolated. X‐ray diffraction studies show 1 to crystallize in the monoclinic space group P2₁/c with a = 1303.7(1) pm, b = 2286.9(2) pm, c = 1063.1(1) pm, β = 94.383(6)°, and Z = 4. 2 crystallizes triclinic in the space group , the cell parameters being a = 1293.2(2) pm, b = 1478.5(4) pm, c = 1507.2(3) pm, α = 98.86(3)°, β = 109.63(2)°, γ = 114.88(2)°, and Z = 2. Both compounds form arrays of eight‐membered rings (SnOPO)₂ linked at the tin atoms to form chains of infinite length. The dimer 3 consists of a like ring, in which the tin atoms are bridged by methoxo groups. It crystallizes triclinic in space group with a = 946.4(1) pm, b = 963.7(1) pm, c = 1174.2(1) pm, α = 82.495(6)°, β = 66.451(6)°, γ = 74.922(6)°, and Z = 1 for the dimer. The Raman spectra of 2 and 3 are given and discussed.     

Electrochemical study of (NEt4)2Cl2FeS2MoS2 and (NEt4)2Cl2FeS2MoS2FeCl2

Summary The ability of [MoS₄]^2–, anions to be used as ligands for transition metal ions has been widely demonstrated, especially with Fe²⁺. The present study has been restricted to linear complexes such as (NEt₄)₂ [Cl₂FeS₂MoS₂] and (NEt₄)₂[Cl₂FeS₂MoS₂FeCl₂]. Their electrochemical properties are described: upon electrochemical reduction, these compounds yield MoS₂, as a black precipitate, and an iron complex in solution, assumed to be [SFeCl₂]^2–. The electrochemical reduction goes through two electron transfers, coupled with the breakdown of the molecular skeleton: a DISPl and an ECE mechanism. Depending on the solvent, the following equilibrium may be observed: [Cl₄Fe₂MoS₄]^2–[Cl₂FeMoS₄]^2–+FeCl₂. The equilibrium constant, K_D, was evaluated by differential pulse polarography. K_D is tightly related to the donor number of the solvent.     

The alkali hypophosphites KH2PO2, RbH2PO2 and CsH2PO2

The structures of the hypophosphites KH₂PO₂ (potassium hypophosphite), RbH₂PO₂ (rubidium hypophosphite) and CsH₂PO₂ (caesium hypophosphite) have been determined by single‐crystal X‐ray diffraction. The structures consist of layers of alkali cations and hypophosphite anions, with the latter bridging four cations within the same layer. The Rb and Cs hypophosphites are isomorphous.     

Syntheses,Spectroscopic Studies,and Crystal Structures of Me2Sn(O2PPh2)2, Ph2Pb(O2PMe2)2, and Ph2Pb(O2PPh2)2

Me₂Sn(O₂PPh₂)₂ ( 1 ), Ph₂Pb(O₂PMe₂)₂ ( 2 ), and Ph₂Pb(O₂PPh₂)₂ ( 3 ) have been synthesized by the reactions of Me₂SnCl₂ or Ph₃PbCl with the corresponding diorganophosphinic acid in methanol. X‐ray diffraction studies show that the diorganophosphinate groups behave as double bridges between the metal atoms leading to polymeric ring‐chain structures with M₂O₄P₂ (M = Pb, Sn) eight‐membered rings. The organic groups bonded to the metal atoms are in trans‐position in the resulting octahedral arrangement around the metal atoms. The IR and the mass spectra were reported and discussed.     

Thermal decomposition of Me3SnO2PCl2, Me2Sn(O2PCl2)2 and Ph3SnO2PCl2

TG and DTA studies on Me₃SnO₂PCl₂, Me₂Sn(O₂PCl₂)₂ and Ph₃SnO₂PCl₂ were carried out under dynamic argon atmosphere. The results show that the decomposition proceeds in different stages leading to the formation of Sn₃(PO₄)₂ as a stable product. This compound was characterized by IR spectroscopy. Decomposition schemes involving reductive elimination reactions were proposed.