硅铝共掺杂对TiO2薄膜结构及性能的影响

采用非水解溶胶-凝胶法制备了Si、Al共掺杂的TiO2薄膜.应用X射线衍射、紫外可见分光光度计研究了Si、Al掺杂对TiO2薄膜晶型转变、晶粒尺寸、光吸收性能及光催化性能的影响.结果表明:适量引入Si、Al后,可显著提高1000℃热处理后TiO2薄膜的光催化活性;当Si/Ti物质的量比为0.2时,薄膜由于混晶结构光催化活性最佳;Si、Al共掺杂能抑制TiO2的晶型转变及TiO2的晶粒生长,且Si、Al共掺杂的抑制作用比单一Si掺杂更有效;当Si/Ti物质的量比为0.15、Al/Ti物质的量比为0.05时,TiO2锐钛矿向金红石的转变温度从750℃提高到1200℃.     

热处理过程对纳米TiO2结构和性能的影响

以钛酸丁酯为钛源,采用溶胶-凝胶法制备纳米TiO2,结合TG-DTA,XRD,TEM等分析了不同热处理温度对纳米TiO2的晶型结构、晶粒粒径及微观形貌的影响.以甲基橙溶液为目标降解物,探讨了热处理温度对纳米TiO2光催化活性影响.利用Eastman的粒子生长理论对晶粒生长的动力学过程进行初步分析.研究表明:随着热处理温度升高,TiO2粒径逐渐从11.2 nm增大到78.6 nm;热处理温度为450～ 550℃时,纳米TiO2晶粒以锐钛矿为主,温度升至650℃时,出现了锐钛矿和金红石的混合相(质量比A∶R =9∶1),此时晶粒对甲基橙的降解率达到97.75;.而煅烧温度高于850℃后,TiO2几乎完全为金红石相,光催化活性显著下降.50;锐钛矿型TiO2转变金红石型TiO2的温度约为730℃,锐钛矿和金红石相晶粒表观活化能分别18.15 kJ/mol和42.56 kJ/mol;晶粒生长最快温度分别为546℃和1280℃.     

La,Pr,Nd掺杂对纳米TiO2光催化性能的影响

采用水解共沉淀法制备了稀土元素(La, Pr, Nd)掺杂量为0.5wt;～1.5wt;的TiO2光催化剂样本,并对其进行了XRD、TG-DTA、TEM、BET和UV-Vis表征.结果表明,所制备的TiO2光催化剂是以锐钛矿晶型为主的纳米颗粒,掺杂抑制了TiO2晶型由锐钛矿向金红石的转变,同时减小了晶粒尺寸、增大了比表面积、提高了吸光度,且使TiO2半导体的吸光范围发生了红移.将制得的TiO2光催化剂应用于溶液中草酸的降解反应,用K2MnO4滴定法分析降解效率,发现经掺杂改性后的TiO2样本光催化效率均有提高.其中,以掺杂量为1.0wt;的La掺杂样本具有最高的降解效率,与纯TiO2样本相比对草酸的降解率提高了近45;.     

La掺杂TiO2薄膜的制备及其光电流研究

采用溶胶凝胶-浸渍提拉法在ITO导电玻璃表面制备了纯TiO2薄膜和La掺杂TiO2薄膜,对其进行350℃、450℃、550℃保温2h热处理.利用XRD、SEM、EDS、XPS对样品结构、形貌、成分进行表征,利用电化学工作站对薄膜进行光电流测试,研究了La掺杂以及不同热处理温度对TiO2薄膜结构及光电流的影响.结果表明:La掺杂有细化TiO2晶粒和抑制锐钛矿相向金红石相转变的作用.随热处理温度提高,纯TiO2薄膜与La掺杂TiO2薄膜光电流密度均先增大后减小,450℃热处理后纯Ti02薄膜光电流密度为180 μA·cm-2,此温度下La掺杂TiO2薄膜光电流密度为650 μA·cm-2,是纯TiO2薄膜的3.6倍.     

水热合成金红石型TiO2纳米晶及形成机理

以TiCl4为原料加水配制成0.5～2.0mol/L的TiOCl2溶液,在反应温度为120～180℃时可获得纳米级针形(轴比4～5)及球形8～10nm的金红石粒子.研究了升温速率、搅拌等对金红石型TiO2纳米晶的粒径及形貌的影响.使用TEM及XRD对产物粒子进行了表征,并初步探讨了金红石纳米晶的形成机理.结果表明:对于一定浓度的TiOCl2溶液,当反应温度高于140℃时,可生成纯相金红石型TiO2纳米晶粒,搅拌和提高升温速率有利于生成纳米球形颗粒.     

锡掺杂二氧化钛相变过程和微结构分析

本文采用溶胶凝胶法制备了锡掺杂纳米二氧化钛,通过高分辨透射电镜法(HRTEM),X-射线衍射法(XRD)等分析手段对样品的相变过程进行了表征.XRD和HRTEM测试表明纯二氧化钛在烧结温度高于500℃时出现金红石相,而25mol; Sn2+掺杂二氧化钛凝胶在300℃烧结2h后少量锐钛矿相析出的同时结晶出金红石相.实验结果表明Sn2掺杂抑制了锐钛矿和金红石相的晶粒长大;Sn2+掺杂明显地促进了锐钛矿向金红石的转变.Sn2氧化后形成Sn4+,Sn4+置换Ti4+而引起二氧化钛晶格膨胀的同时晶格畸变应力增加.     

Ag修饰TiO2的制备及其在模拟太阳光下的光催化性能研究

采用溶胶凝胶法制备了不同浓度Ag修饰TiO2以及纯TiO2,采用X射线衍射(XRD)、能谱分析(EDS)、X射线光电子能谱(XPS)、扫描电子显微镜(SEM)、紫外可见光谱(UV-Vis)、荧光光谱(PL)等测试技术对其进行了系统的表征.结果表明,纯TiO2为锐钛矿/金红石混晶结构,Ag-TiO2为锐钛矿结构,Ag加入细化了TiO2晶粒尺寸,并且抑制了锐钛矿向金红石的转变,Ag元素加入后以单质形式存在.以罗丹明B溶液为目标污染物,研究了样品在模拟太阳光下的光催化性能,实验结果表明,Ag-TiO2的光催化活性较纯TiO2有明显提升,4;Ag-TiO2降解率最高,3 h后对罗丹明B的降解率达到83.3;,比纯TiO2降解率提高了68.6;,其反应速率常数k为0.00896 min-1,为纯TiO2的3.12倍.     

镧掺杂混晶结构TiO2纳米粉体的制备及其光催化性能

以钛酸四丁酯为Ti源,采用溶胶-凝胶自蔓燃法制备了镧掺杂的La-TiO2(简写为LT)纳米粉体.利用X射线粉末衍射(XRD)、红外光谱(FIIR)、透射电子显微镜(TEM)等对掺杂型TiO2粉体的晶型结构与颗粒尺寸等进行表征.利用紫外-可见光吸收光谱(UV-vis)研究了H2O2改性、镧掺杂量以及混晶结构对TiO2纳米粉体降解甲基橙的影响.结果表明:镧掺杂混晶TiO2粉体的光催化活性明显优于未掺杂的锐钛矿TiO2粉体.当La3+掺杂量为0.5;,合成温度为475℃(金红石相含量为26.0;)时,得到的TiO2粉体光催化活性最好.H2O2的加入有助于TiO2光催化剂表面的电子-空穴对生成,提高光催化剂对甲基橙的降解率,当H2O2浓度为6;时,光照3h后,降解率达到了91.97;.     

胶原纤维为模板制备Gd掺杂纤维状二氧化钛及光催化性能研究

以胶原为模板剂、硫酸钛为钛源、硝酸钆为掺杂源制备了钆掺杂纤维结构TiO2(Gd-TiO2).通过扫描电镜(SEM)、X射线衍射仪(XRD)、紫外可见漫反射光谱(UV-Vis-DRS)、X射线光电子能谱(XPS)对样品的表面形貌、晶相组成、紫外吸收带、元素组成及化合价态进行了分析.以甲基橙为目标降解物,研究了样品的光催化性能并确定钆的最佳掺杂量.结果表明:600℃煅烧温度下2;Gd-TiO2纤维结构完好、光催化效果最好,光反应30 min后其降解率达到91.89;,比起未掺杂试样大大提高.钆掺杂会改变TiO2的晶粒尺寸并能够抑制TiO2从锐钛矿相向金红石相转变,掺杂后紫外吸收带发生蓝移.     

钒掺杂纳米二氧化钛的制备及光催化活性研究

以钛酸四丁酯为钛前驱体,偏钒酸铵为掺杂离子给体.采用溶胶-凝胶法制备了V掺杂纳米二氧化钛粉体;并使用TGA-DSC、XRD、BET、SEM对其晶化温度与结构进行了表征.结果表明:V掺入促进锐钛矿相向金红石相转变、抑制晶粒长大、增大比表面积,纳米粉体颗粒呈分布较均匀的类球形晶粒.以亚甲基蓝为模型反应,考察了V掺杂量、煅烧温度对催化剂光催化性能的影响,结果表明:V掺杂的TiO2 粉体降解亚甲基蓝符合一级反应动力学规律;晶格中V4+能够作为电荷转移物种,有效的抑制光生电子与空穴的复合,增加了表面空穴浓度,提高TiO2 纳米粉体的光催化活性,当掺杂量为1.5 mol;,煅烧温度为450 ℃时,TiO2 具有最佳的光催化性能.     

CsI-LiCl共晶材料的坩埚下降法生长与闪烁性能研究

本文采用坩埚下降法,在真空密封的石英坩埚中成功生长出CsI-LiCl与CsI-LiCl:Na共晶闪烁体。通过扫描电子显微镜(SEM)观察晶体微结构表明该共晶中LiCl相与CsI相存在周期性的层状排列,CsI相的厚度在5 μm左右。共晶样品的X射线激发发射谱显示在CsI-LiCl和CsI-LiCl:Na共晶样品存在缺陷发光,在CsI-LiCl样品中还观察到了纯CsI的自陷激子(STE)发光。CsI-LiCl样品在α粒子激发下的多道能谱中观察到明显的全能峰,这一结果证明CsI-LiCl共晶可用于热中子探测的潜力。     

静电纺丝法制备CeO2微纳米纤维及其除氟性能

以聚丙烯腈(PAN)为载体,六水合硝酸铈[Ce(NO₃)₃·6H₂O]为原料,采用静电纺丝法制备了Ce(NO₃)₃/PAN纤维,在空气中热处理得到CeO₂微纳米纤维,通过XRD、BET和SEM对CeO₂微纳米纤维进行表征。采用静态吸附实验探讨了CeO₂微纳米纤维去除水溶液中氟离子的性能,考察了溶液pH值、初始氟离子浓度及共存阴离子等对吸附性能的影响。结果表明,pH=3时,CeO₂微纳米纤维对F^-的吸附性能最佳,CeO₂吸附量随着F^-浓度的增大呈上升趋势。CeO₂微纳米纤维对F^-的吸附等温线遵循Langmuir模型,二级动力学模型能很好地描述CeO₂微纳米纤维对F^-的吸附过程。CeO₂微纳米纤维的除氟性能优良,可为其实际应用提供理论参考。     

Selinidin: Crystal structure generated by C–H···O, C–H···π and π-π interactions

The title compound, 9,10-dihydro-8,8-dimethyl-2-oxo-2H,8H-benzo[1,2-b:3,4-b']dipyran-9-yl-2-methyl-2-butenoate, C₁₉H₂₀O₅, was isolated from the roots of Selinum vaginatum. The compound crystallizes into monoclinic space group P2 ₁ with unit cell parameters: a = 12.830(2) Å, b = 9.041(1) Å, c = 14.983(1) Å, β = 95.09(1)°, Z = 4. The crystal structure has been determined using direct methods and refined by full-matrix least-squares to a final R value of 0.0529 for 3142 observed reflections. There are two independent molecules, A and B, per asymmetric unit. In both the molecules, the coumarin nucleus is planar. However pronounced differences are observed in the conformation of dihydropyran ring which has a half-chair conformation with an 8β-9α orientation in molecule A and is intermediate between half-chair and sofa in molecule B. Differences also occur in the conformation of the 2-methylbutenoyloxy side chain at C9 due to the different geometry of C–H···π interactions in molecules A and B. Molecules A and B are connected by π–π interactions between their coumarin fragments forming dimers. The dimers interact through C–H···O and C–H···πhydrogen bonds.     

Chromene and Imidazole Based D-π-A Chemosensor Preparation and Its Anion Responsive Effects

We have designed and synthesized the colorimetric chemosensor through the reactions of 2-(4H-chromen-4-yildene)malonitrile and 4-imidazolecarboxaldehyde. Due to its well conjugated D-π-A system and the existence of NH- fragment in structure, we expected that the chemosensor can detect anion using NH- fragment in the imidazole moiety of the structure. In this regard, UV-Vis absorption spectra were measured to investigate sensing properties of the probe toward different anions in DMSO. This chemosensor can detect both fluoride and cyanide ion with absorption change in intensity. In addition, pH sensing property was also investigated upon the addition of hydroxide ion. These properties are related to the deprotonation effect. The ICT system in this molecule was also observed by the computational approach using Material Studio 4.3 package.     

电子显微分析在表征纳米晶体化学组分中的应用

纳米材料的化学组分及含量影响其光、电、声、热、磁等物理性能,电子显微分析是表征纳米晶体化学组分的重要方法之一.本文综述了X-射线能谱(EDS)、X-射线波谱(WDS)、电子能量损失谱(EELS)和选区电子衍射(SAED)等现代电子显微分析技术在表征纳米晶体化学组分、形貌、尺寸和结构等方面的应用及其研究进展,并比较了这些分析方法存在的差异,提出了其应用中存在的不足及今后的研发方向.     

4- and 5-nitroindane

Mononitration of indane produces a mixture of 4- and 5- nitroindanes. Crystallization from mixtures occurs after distillation improves composition of a major component to above 80%. 4-Nitroindane: triclinic, space group (#2),a=7.332(4) Å,b=8.304(4) Å,c=8.358(4) Å, =61.43(4)°, =67.60(4)°, =70.15(4)°,V=405.4(4) ų,Z=2. Non-H-atoms are nearly planar, aliphatic H's are eclipsed. 5-Nitroindane: monoclinic, space groupP2₁/c (#14),a=10.946(8) Å,b=15.643(10) Å,c=9.415(6) Å, =92.34(5)°,V=1611(2) ų,Z=8. Non-H-atoms in the two molecules differ in torsion of the nitro group with respect to indane and fold of the nonbenzylic methylene group. Semiempirical calculations (PM3) suggest that distorsion from planarity may be associated with the two lowest energy vibrational modes. Uv, ir, ms, proton, and¹³C-nmr spectra are correlated with the solid state structures.     

6<Emphasis Type="Italic">S</Emphasis>,8α-Dihydroxy-14,15-Dihydrocarapin (Khayanone) from the Stem Bark of <Emphasis Type="Italic">Khaya Senegalensis</Emphasis> (Meliaceae): Isolation and its Crystal Structure

Khayanone was isolated from the stem bark of African mahogany, Khaya senegalensis (Meliaceae), and characterized as 6S,8α-dihydroxy-14,15-dihydrocarapin on the basis of spectral analysis and single crystal X-ray diffraction study. The compound crystallizes in the tetragonal space group P4 ₁ 2 ₁ 2 with unit cell parameters: a = 13.2315(19) Å, c = 29.118(6) Å, Z = 8. The crystal structure has been solved by direct methods and refined to R = 0.0375 for 4552 unique reflections. The six-membered rings A and B exist in boat conformations, rings C and D in chair conformations, and the furan ring is planar. The crystal structure is stabilized by O-H···O and C-H···O interactions. This is the first report about 6S configuration of mexicanolide revealed by X-ray diffraction analysis. The configuration of oxygenated C-6 in mexicanolide-group limonoids is discussed.     

Nuclear magnetic resonance: a powerful tool to study liquid crystals

Nuclear magnetic resonance (NMR) is a spectroscopic technique widely used to investigate materials and soft matter in particular. In this brief review, the main uses of NMR techniques to investigate different aspects of liquid crystals, such as the orientational and dynamic properties, the supramolecular structure and average molecular conformations, are described. In the second part of the paper, the case study of a ‘de Vries’ liquid crystal is reported and the main results obtained by combining different NMR techniques are discussed.     

X-ray analysis of sideroxol from <Emphasis Type="Italic">Sideritis leptoclada</Emphasis>

Sideroxol (1), a kaurane diterpene which has the ent-7α,18-dihydroxy-15β,16β-epoxykaurane structure (MW = 320.47, C₂₀H₃₂O₃) was obtained from the acetone extract of Sideritis leptoclada plant as well as from some other Sideritis species. It crystallizes in the orthorhombic space group P2₁, 2₁, 2₁ with a = 10.967(3), b = 24.555(5), c = 6.372(4) Å, Dc = 1.240 g cm⁻³, Z = 4, and refines to R = 0.065 for 721 independent reflections. The skeleton consists of three fused six-membered rings and a five-membered ring with fused epoxide. The six membered rings exhibited slightly distorted chair conformation. In addition to sideroxol, two kaurane and five kaurene diterpenes were isolated from the hexane and acetone extracts of the studied plant.     

New zeotype borophosphates with chiral tetrahedral topology: (H)0.5M1.25(H2O)1.5[BP2O8]·H2O (M = Co(II) and Mn(II))

Two new isostructural open‐framework zeotype transition metal borophosphate compounds, (H)_0.5M_1.25(H₂O)_1.5[BP₂O₈]·H₂O (M = Co(II) and Mn(II)) were synthesized by mild hydrothermal method. The structure of compounds were characterized by single‐crystal X‐ray diffraction which have ordered, alternating, vertex‐sharing BO₄, PO₄, and (MO₄)OM(H₂O)₂ groups with hexagonal, P 6₁ 2 2 (No 178) space group and unit cell parameters for Co a = 9.4960(6) Å, c = 15.6230(13) Å, for Mn a = 9.6547(12) Å, c = 15.791(3) Å, Z = 1 for both of them. TGA/DTA analysis, IR spectroscopy were used for characterization. Magnetic susceptibility measurements for both of the compound indicate strong antiferromagnetic interaction between metal centers. (© 2005 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)