压力诱导相变原位构建BiVO4/Bi0.6Y0.4VO4型异质结增强光催化全解水性能

光催化完全分解水制氢是一个在粉末颗粒中实现多个串行物理化学步骤的复杂反应过程.这一过程在理论上具有体系简单、成本低、易操作等特点.然而,单步光激发系统中通常存在严重的光生载流子复合,这极大地制约了光催化的整体效率.利用能带结构不同的半导体合理构建异质结催化剂被认为是解决这一难题的重要途径之一.特别是近年来,S型异质结概念的提出为设计异质结结构以及分析不同半导体之间的载流子迁移问题提供了新的思路.本文以小粒径BiVO₄/Bi_0.6Y_0.4VO₄(BYV)为研究对象,首先利用"共沉淀-晶化"的方法制备了BYV固溶体纳米颗粒,随后利用压力诱导固溶体中四方相钒酸铋结构转变为单斜相,从而构建了BiVO₄/Bi_0.6Y_0.4VO₄复合光催化剂.XRD,Raman,HRTEM,HAADF-EDS的结果表明,经过高压后处理的BYV固溶体表面会出现粒径约为5 nm单斜钒酸铋纳米颗粒,实现了原位构建异质结结构.随后载流子动力学的相关表征以及Au选择性光沉积的结果表明,在光照条件下,所构建异质结中的光生电子主要分布在BYV固溶体上,而在表面形成的单斜相钒酸铋颗粒主要起到了类似"空穴"捕获的作用.这种在异质结中的载流子迁移路径符合S型异质结机理.电化学、稳态荧光光谱以及瞬态荧光光谱的表征结果表明,相比于单一固溶体,在S型异质结这种两步激发系统中所存在的载流子迁移路径能够大幅促进光生载流子分离,从而提高了小粒径BYV的光催化完全分解水性能.综上,构建S型异质结是一种解决小粒径光催化剂中载流子分离能力差的有效途径.同时,压力诱导材料晶型转变实现原位构建异质结的制备方法也为提高光生载流子分离效率提供了新的研究思路与机遇.     

硫化钴装饰BiVO4光阳极提升其光电化学水分解性能

太阳能驱动的光电化学(PEC)水分解可以有效地将太阳能转化为化学能,作为解决环境排放和能源危机最具前景的途径之一,已经引起了科学界的广泛关注.PEC水分解系统由两个半反应组成:在光阳极上的析氧反应(OER)和光阴极上的析氢反应(HER).PEC系统的太阳能转化效率主要由光阳极/电解质界面的OER过程所决定,这是一个非常复杂且涉及质子偶联的多步四电子转移过程.钒酸铋(BiVO₄)是应用于PEC水分解的典型且具有实际应用前景的光阳极材料之一.然而,由于不良的表面电荷转移、电荷在光阳极/电解质结面处的表面复合以及缓慢的OER动力学等因素,导致BiVO₄的PEC性能受到严重限制.本文开发了一种新颖有效的解决方案,以低成本、高电导率和具有快速电荷转移能力的硫化钴装饰来提升BiVO₄光阳极的PEC活性,X射线多晶衍射(XRD)、X射线光电子能谱(XPS)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)等表征,研究结果表明CoS成功装饰于BiVO₄表面.采用紫外-可见吸收光谱(UV-VisDRS)研究了BiVO₄和复合光阳极CoS/BiVO₄的光学性质,结果表明,与纯的BiVO₄相比,CoS/BiVO₄光阳极在可见光范围内光吸收能力有所增强.将制备的BiVO₄和CoS/BiVO₄光阳极应用于PEC分解水实验中,结果表明,相对于1.23 V可逆氢电极,在光照下,CoS/BiVO₄光阳极的光电流密度显著提升,可高达3.2 m Acm^-2,是纯BiVO₄的2.5倍以上.与纯BiVO₄相比,CoS/BiVO₄光阳极的起始氧化电位显示出负向偏移0.2 V,表明析氧过电势得到有效减小.入射光子转换效率(IPCE)测试结果表明,CoS/BiVO₄光阳极的入射光子转换效率在500 nm之前的可见光范围内得到明显提升,其中,CoS/BiVO₄的IPCE值在380 nm处达到最大.此外,由于CoS的装饰作用,CoS/BiVO₄光阳极的电荷注入效率和电荷分离效率均得到较大的提升,分别达到75.8%(相较于纯BiVO₄光阳极的36.7%)和79.8%(相较于纯BiVO₄光阳极的66.8%).电化学阻抗谱(EIS)测试结果表明,通过CoS的装饰,CoS/BiVO₄光阳极的界面电荷转移电阻得到有效降低,证明其界面电荷转移动力学得到有效提升.光致发光光谱测试结果表明,CoS的装饰显著提高了BiVO₄的光生电子-空穴对的分离效率,进一步证明BiVO₄表面的CoS装饰在其PEC分解水中起着非常积极的作用.本文为通过表面修饰设计应用于PEC水分解的有效的光阳极提供了新思路.     

水中药物和个人护理品分析方法研究进展

随着社会经济发展水平的提高和医疗条件的改善,药物和个人护理品(PPCPs)的使用种类及总量均显著增加,造成环境中PPCPs的残留浓度不断升高,进而会对水环境生态安全及人类和动植物的健康造成潜在危害和严重威胁.由于开发建立快速、灵敏、高效的PPCPs定性、定量分析方法是探究其存在、去除及毒性的前提,因此本文对水中PPCP...     

NaY分子筛Lewis酸促进甲醇经亚硝酸甲酯分解制二甲氧基甲烷※

二甲氧基甲烷(Dimethoxymethane, DMM)作为一种基础有机化学品, 在树脂、溶剂、燃料等领域具有广泛用途. 传统合成方法采用甲醇甲醛缩合, 反应效率比较低. 亚硝酸甲酯(CH₃ONO)是一种性质活泼的气体, 可由甲醇、O₂、NO在无需催化剂的条件下获得, 其反应活性比甲醇高很多. 通过亚硝酸甲酯在常压条件下催化分解可以高效制备DMM. 本工作系统研究了不同类型分子筛的酸性对亚硝酸甲酯催化分解制备DMM的影响规律, 催化活性顺序为: NaY (97%)=HY (97%)>HZSM-5 (90%)>Hβ (89%)>NaZSM-5 (18%)>Naβ (6%), DMM选择性顺序为: NaY (53%)>HY (12%)=Naβ (12%)>NaZSM-5 (7%)>Hβ (4%)>HZSM-5 (3%), 其中NaY分子筛是一种性能优异的亚硝酸甲酯分解制备DMM的催化剂. 通过X射线衍射(XRD)、比表面及孔隙度分析(BET)、扫描电子显微镜(SEM)、吡啶红外(Py-FTIR)等结构表征手段, 发现分子筛的酸性位点是促进亚硝酸甲酯分解的活性中心, 而Na⁺和Al物种的Lewis酸是高选择性生成DMM的关键. 本工作可为DMM提供一种新的高效合成路线.     

富晶格位错的多孔铋纳米花高效电还原二氧化碳制甲酸盐※

二氧化碳转化已成为现今世界研究的热点. 本工作采用原位电化学转化的策略, 将简单溶剂热法合成的层状甲酸氧铋纳米花(BiOCOOH NFs)还原为带有大量晶格位错的多孔铋纳米花(p-Bi NFs). 研究结果表明, p-Bi NFs电催化二氧化碳转化为甲酸盐具有较小的过电位(436 mV). 在–1.8 V(相对饱和甘汞电极, vs. SCE)时, 甲酸盐的分电流密度(j_formate)高达24.4 mA•cm^-2, 法拉第效率(FE_formate)为96.7%, 且在超过500 mV的宽电位窗口内FE_formate超过90%, 并具有很好的稳定性. 该催化剂的高催化性能可归因于前驱体晶格坍塌和重构而形成特殊的多孔粗糙的微纳多级结构, 其表面富含晶格位错和缺陷等高本征活性位, 且具有较强的电子传递能力. 本研究为设计合成高性能的电催化二氧化碳还原产甲酸催化剂提供了新的思路.     

Synthesis and magnetic properties of trinuclear nickel(II) complexes bridged by α-benzyldioximato groups

Four new NiII–NiII–NiII homotrinuclear complexes namely [Ni(-BD)2{NiL2}](ClO4)2 [L = 1,10-phenanthroline (phen), 5-nitro-1,10-phenanthroline (5-NO2-phen), 2,2-bipyridyl (bpy) or 4,4-dimethyl-2,2bipyridyl (Me2bpy) and (-BD)– = -benzyldioximato ion] have been prepared and characterized. Based on elemental analyses, i.r. spectra, conductivity measurements, extended -benzyldioximato-bridged systems consisting of three nickel(II) ions in which the central nickel(II) ion has a square-planar environment and the end capped two nickel(II) ions have a distorted octahedral environment are proposed for these structures. The temperature dependence of the magnetic susceptibility for complexes (1) (phen), (2) (5-NO2-phen), (3) (bpy) and (4) (Me2bpy) were measured over the 77–300 K range and the observed data were successfully simulated by an equation based on the spin Hamiltonian operator (H^ = –2JS^1S^2), giving the exchange integral J = –13.31 cm–1 for (1), J = –7.37 cm–1 for (2), J = –8.96 cm–1 for (3) and J = –7.33 cm–1 for (4) These results indicate a weak antiferromagnetic spin exchange interaction between the two terminal nickel(II) io     

Photodynamic Therapy of 9L Gliosarcoma with Liposome-Delivered Photofrin

Abstract— The effect of Photofrin encapsulated in a liposome delivery vehicle for photodynamic therapy (PDT) of the 9L gliosarcoma and normal rat brain was tested. We hypothesized that the liposome vehicle enhances therapeutic efficacy, possibly by increasing tumor tissue concentration of Photofrin. Male Fisher rats bearing a 9L gliosarcoma were treated 16 days after intracerebral tumor implantation with either Photofrin in dextrose (n = 5) or Photofrin in liposome (n = 6). Nontumor-bearing animals were treated with Photofrin delivered either in dextrose (n = 4) or liposome (n = 4) vehicle. Tissue concentrations of Photofrin delivered either in dextrose (n = 4) or liposome (n = 4) vehicle were measured in tumor, brain adjacent to tumor and in normal brain tissue. Photofrin was administered (intraperitoneally) at a dose of 12.5 mg/kg and PDT (17 J/cm₂ of 632 nm light at 100 mW/cm₂) was performed 24 h after Photofrin administration. Brains were removed 24 h after PDT and stained with hematoxylin and eosin for analysis of cellular damage. The PDT using Photofrin in the liposome vehicle caused significantly more damage to the tumor ( P < 0.001) than did PDT with Photofrin in dextrose. The PDT of tumor with Photofrin delivered in liposomes caused a 22% volume of cellular necrosis, while PDT of tumor with Photofrin delivered in dextrose caused only scattered cellular damage. Photofrin concentration in tumors was significantly higher ( P = 0.021) using liposome (33.8 ± 18.9 μg/g) compared to dextrose delivery (5.5 ± 1.5 μg/g). Normal brain was affected similarly in both groups, with only scattered cellular necrosis. Our data suggest that the liposome vehicle enhances the therapeutic efficacy of PDT treatment of 9L tumors.     

Silicone-modified starch/protein microparticles: protecting biopolymers with a hydrophobic coating

Silicone-coated starch/protein (human serum albumin, HSA) microparticles were prepared by precipitation of a starch/HSA/DMSO/water (water-in-oil) emulsion into acetone containing a silicone: the silicone polymer was either unfunctionalized (SiMe₃ terminated, PDMS) or functionalized at its termini with Si(OEt)₃ groups (TES-PDMS). The microparticles of approximate diameter 2–7 μm were highly hydrophobic with advancing contact angles 115°. Over several minutes, however, the contact angle decreased to ca. 40–70°. Soxhlet extraction with water led to degradation of the microparticles, irrespective of the nature of their silicone coating, as evidenced by release of the protein from them. Intraperitoneal (IP) or gastric administration of the two different particles to mice, however, showed a clear difference between the two silicones. The microparticles coated with either PDMS or TES-PDMS led to very different immune responses. Oral administration of the microparticles prepared with functionalized silicone elicited a significant production of antibodies, whereas the particles prepared with the unfunctionalized silicone (PDMS) were only weakly active. By contrast, the IP results demonstrated that particles coated with PDMS elicited an immune response that was established much more rapidly than with the particles modified with TES-PDMS. It is proposed that the TES-PDMS forms a physically adhering film or covalent bond to the protein molecules, which serves to protect the microparticle from biological degradation in the gut and/or facilitates the microparticle/protein interaction with the immune system.     

用于可充电器件的有机电极材料

有机化合物作为可充电器件的电极材料可以通过自身电活性部位电荷状态的变化来实现本征的氧化还原反应.除了锂离子电池外,有机电极材料还可以用于其他离子半径更大的金属离子电池(如Na+、K+、Mg2+、Zn2+等).有机电极材料还具有诸多优势,比如结构多样、成本低廉、资源丰富和可持续性高,易于通过适当的材料设计调整其性能等,已...     

Boron group element doping of Li1.5Al0.5Ge1.5(PO4)3 based on microwave sintering

Journal of Solid State Electrochemistry - We report effectiveness of dopants selected from group 13, such as B, Ga, and In, on the conductivity of Li1.5Al0.5Ge1.5(PO4)3 (LAGP) that is recognized as...