氧化锌微球和层状集聚体的控制合成及其光致发光

通过锌片与水分别在乙二醇和乙二胺中120℃反应12 h,直接在锌片上原位合成出ZnO微球和层状集聚体.利用X射线粉末衍射、扫描电子显微镜、透射电子显微镜和红外光谱对产物进行了表征和分析.结果表明,在乙二醇中得到的直径为0.3～2 μm ZnO微球是由直径为30～50 nm纤锌矿结构的ZnO纳米片通过氢键组装而成;在乙二胺中得到的层状集聚体是由20～30 nm的纤锌矿结构的ZnO纳米晶通过氢键组装成尺寸约为450 nm×900 nm纳米片,这些较大尺寸纳米片再通过范德华力组装而成.研究了乙二醇和乙二胺在ZnO微球和层状集聚体形成过程中的作用并提出了可能的生长机理.在波长为300 nm光的激发下,发现ZnO微球和层状集聚体具有发光峰位于397 nm强的紫外光发光、485和520 nm弱的蓝绿光发光,它们分别起源于ZnO宽带隙的激子发射,氧空位与间隙氧之间的跃迁以及表面上离子化氧空位中的电子与价带中光激发的空穴之间的复合.     

图案化锥形氧化锌纳米带的原位热氧化法制备与发光性质

采用光刻技术制备出图案的锌膜,所得锌膜与纯氧在700℃氧化反应10 min,在锌膜的表面上原位生长出具有图案的锥形ZnO纳米带阵列,实现了ZnO纳米带生长位置的可控生长。锌膜上得到的锥形ZnO纳米带为单晶六方纤锌矿结构,长度在1～4μm,纳米带根部和顶部的宽度分别在300～700 nm和100～300 nm。提出了锥形ZnO纳米带的可能生长机理。在波长为300nm光的激发下,发现了锌膜上锥形ZnO纳米带具有发光峰位于395 nm弱的紫外光发光和510 nm强的蓝绿光发光,它们分别起源于ZnO宽带隙的激子发射以及表面上离子化氧空位中的电子与价带中光激发的空穴之间的复合。     

ZnO纳米片组装的微球和层状集聚体的控制合成及其发光性质

通过锌片与水分别在乙二醇和乙二胺中120 ℃反应12 h,直接在锌片上原位合成出ZnO纳米片组装的微球和层状集聚体。利用X射线粉末衍射、扫描电子显微镜、透射电子显微镜和红外光谱对产物进行了表征和分析。结果表明,在乙二醇中得到的直径为0.3～2 µmZnO微球是由直径为30～50 nm纤锌矿结构的ZnO纳米片通过氢键组装而成;在乙二胺中得到的层状集聚体是由20～30 nm的纤锌矿结构的ZnO纳米片通过氢键组装成尺寸约为450×900 nm纳米片,这些较大尺寸纳米片再通过范德华力组装而成。研究了乙二醇和乙二胺在ZnO微球和层状集聚体形成过程中的作用并提出了可能的生长机理。在波长为300 nm光的激发下,发现ZnO微球和层状集聚体具有发光峰位于397 nm强的紫外光发光、485和520 nm弱的蓝绿光发光,它们分别起源于ZnO宽带隙的激子发射,氧空位与间隙氧之间的跃迁以及表面上离子化氧空位中的电子与价带中光激发的空穴之间的复合。     

β-Ga2O3:Dy3+ 纳米棒束的制备和光致发光性质

采用水热法及后续热处理制备了β-Ga2O3：Dy^3＋纳米棒束. 利用X射线粉末衍射（XRD）, 场发射电子扫描显微镜（FESEM）、发光光谱等测试手段对β-Ga2O3：Dy^3＋的物相、形貌、发光性质等进行了研究. FESEM等测试表明水热样品是由直径约100 nm, 长约2 μm的纳米棒组成的长径比约为3的羟基氧化镓（GaOOH）纳米棒束. 经过900 ℃高温热处理, 得到了形貌和尺寸基本保持不变的β-Ga2O3：Dy^3＋纳米棒束. 光致发光测试表明, Dy^3＋的发光由分别归属于4F9/2-6H15/2的蓝光（460～505 nm, 491 nm为最强峰）和4F9/2-6H13/2的黄光（570～600 nm, 580 nm为最强峰）组成. Β-Ga2O3基质可以有效地向Dy^3＋传递能量. 与固相法样品相比, 采用水热后续热处理方法制备的样品在分散性、形貌、能量传递和寿命方面明显优于固相法样品.     

α-Fe2O3掺杂对In2O3电导和气敏性能的影响

用化学共沉淀法制备了α Fe2O3掺杂的In2O3纳米晶微粉,研究了α Fe2O3掺杂对In2O3电导和气敏性能的影响. 结果表明, α Fe2O3和In2O3间可形成有限固溶体In2－xFexO3(0≤x≤0.40); Fe3＋对In2O3晶格中In3＋格位的部分取代,大大增强了阴阳离子间的结合力,导致材料中氧空位VO×数骤降、 自由电子的浓度变稀和电导下降. n(Fe3＋):n(In3＋)=5 :5的共沉淀粉于800 ℃下灼烧4 h所得的α Fe2O3掺杂In2O3传感器元件,对45 μmol•L－1 C2H5OH的灵敏度达54.0,为相同浓度干扰气体汽油的8倍多.     

ZnO纳米片组装的微球和层状集聚体的控制合成及其发光性质

通过锌片与水分别在乙二醇和乙二胺中120 ℃反应12 h,直接在锌片上原位合成出ZnO纳米片组装的微球和层状集聚体。利用X射线粉末衍射、扫描电子显微镜、透射电子显微镜和红外光谱对产物进行了表征和分析。结果表明,在乙二醇中得到的直径为0.3～2 µmZnO微球是由直径为30～50 nm纤锌矿结构的ZnO纳米片通过氢键组装而成;在乙二胺中得到的层状集聚体是由20～30 nm的纤锌矿结构的ZnO纳米片通过氢键组装成尺寸约为450×900 nm纳米片,这些较大尺寸纳米片再通过范德华力组装而成。研究了乙二醇和乙二胺在ZnO微球和层状集聚体形成过程中的作用并提出了可能的生长机理。在波长为300 nm光的激发下,发现ZnO微球和层状集聚体具有发光峰位于397 nm强的紫外光发光、485和520 nm弱的蓝绿光发光,它们分别起源于ZnO宽带隙的激子发射,氧空位与间隙氧之间的跃迁以及表面上离子化氧空位中的电子与价带中光激发的空穴之间的复合。     

双功能催化剂催化CO2加氢制低碳烯烃反应中In2O3的尺寸效应

CO2催化加氢转化成高附加值化学品如低碳烯烃(C2=–C4=)等是减少碳排放的有效途径之一.采用金属氧化物/分子筛双功能催化剂可以实现CO2加氢直接高选择性合成C2+碳氢化合物.通常认为,金属氧化物组分可以活化CO2转化为甲醇等含氧中间体,该中间体在分子筛孔道内进一步转化为各种烃.氧化铟(In2O3)/SAPO-34双功能催化剂由于具有出色的催化CO2加氢制低碳烯烃反应性能而备受关注,然而,仍需进一步提升催化剂的催化性能以推动该反应的工业应用.目前,氧化物的结构与双功能催化剂性能之间的关系还不明确,这不利于其催化性能的改善.现有关于金属氧化物纳米粒子的尺寸(特别是小于23 nm)效应及其对双功能催化CO2加氢反应的活性和产物分布的影响的报道较少,对此深入理解将有利于设计更高性能的催化剂.本文采用沉淀法,通过控制焙烧温度得到了一系列尺寸为7～28 nm的立方相In2O3,通过多种表征手段探究了In2O3的尺寸对其结构与表面化学性质的影响.结果表明,随着In2O3晶粒尺寸的减小,其氧空位数目、CO2、H2与NH3吸附量以及Lewis较强酸性位比例均逐渐增加.在350oC,3 Mpa,9000 mL·gcat–1·h–1和H2/CO2比为3的反应条件下,研究了In2O3/SAPO-34双功能催化剂中In2O3粒径对其催化CO2加氢制低碳烯烃反应性能的影响.结果表明,随着双功能催化剂中In2O3尺寸的增大,低碳烯烃(尤其是丙烯)选择性、收率及烯烃与烷烃比例均先升高后降低,在尺寸为19 nm的In2O3上达到最大值,分别为76.9％、12.3 mmol goxide–1 h–1和4.8.较小尺寸的In2O3虽然具有较大的比表面积和更多的氧空位,并为CO2和H2的活化提供了更多的活性位,但小于19 nm的颗粒更容易烧结;In2O3的尺寸还会影响其与SAPO-34的协同效应,进而影响双功能催化剂的催化活性.此外,相对于其它尺寸的In2O3,19 nm的In2O3更有利于甲醇中间体的生成.因而19 nm In2O3耦合SAPO-34的双功能催化剂性能最好,其催化CO2转化率最高,为14.1％.综上,适中尺寸的In2O3能够促进In2O3/SAPO-34上CO2加氢制低碳烯烃反应.这些结果为通过平衡结构稳定性和催化性能来设计更有效的催化CO2转化的复合催化剂提供了理论指导.     

GaN纳米棒的催化合成及其发光特性

使用稀土元素Tb作催化剂, 通过氨化溅射在Si(111)衬底上的Ga2O3/Tb薄膜, 成功制备出GaN纳米棒. X射线衍射测试显示, GaN纳米棒具有六方结构. 利用扫描电子显微镜和高分辨透射电子显微镜观察分析得出, 纳米棒为单晶GaN, 纳米棒的直径为50-150 nm, 长度约10 μm. 光致发光谱在368.6 nm处有一强的紫外发光峰, 说明纳米棒具有良好的发光特性. 讨论了GaN纳米棒的生长机制.     

ZnO纳米片自组装空心微球的无模板水热法制备与发光性质

报道了一种简单的制备ZnO纳米片自组装成空心微球的无模板水热法. 即通过醋酸锌与水和乙二醇混合溶剂(V_水/V_乙二醇 = 1/20)在100℃水热反应12 h合成了ZnO空心微球. 利用扫描电子显微镜、透射电子显微镜、X 射线衍射仪和红外光谱对产物进行了表征和分析. 结果表明, 所制备ZnO空心微球的直径为2~5 μm, 它是由直径为10~20 nm纤锌矿结构的ZnO纳米片自组装而成. 研究了水与乙二醇的体积比及反应时间对产物形貌的影响, 结果表明乙二醇在ZnO纳米片的形成与自组装过程中起着关键作用, 并提出了可能的生长机理. 在波长为300 nm光的激发下, 发现ZnO空心微球具有发光峰位于397 nm强的紫外光发光和486 nm弱的蓝绿光发光, 这两种发光分别起源于ZnO宽带隙的激子发射和氧空位与间隙氧之间的跃迁.     

掺铟氧化锌纳米盘的制备、结构及性质研究

热蒸发Zn、In₂O₃和C粉混合物, 在没有催化剂的条件下制备出掺铟氧化锌纳米盘. 纳米盘呈六边形或十二边形, 均是结晶完好的纤锌矿结构的单晶, 对角线长度约1~3 μm , 厚度40~100 nm. 纳米盘的生长是由自催化固-液-气(V-L-S)机理控制, 在实验条件下Zn和In的液滴抑制纳米盘 [0001]方向的生长. EDS分析表明, 六边形纳米盘和十二边形纳米盘中In的含量相近, 约为2.2%. 室温光致发光谱显示掺杂后的紫外发射峰位稍有蓝移, 同时半高宽(HWHM)变大, 没有观察到绿光发射峰位.     

In(OH)3 and In2O3 nanorod bundles and spheres: microemulsion-mediated hydrothermal synthesis and luminescence properties

Indium hydroxide, In(OH)3, nano-microstructures with two kinds of morphology, nanorod bundles (around 500 nm in length and 200 nm in diameter) and caddice spherelike agglomerates (around 750-1000 nm in diameter), were successfully prepared by the cetyltrimethylammonium bromide (CTAB)/water/cyclohexane/n-pentanol microemulsion-mediated hydrothermal process. Calcination of the In(OH)3 crystals with different morphologies (nanorod bundles and spheres) at 600 degrees C in air yielded In2O3 crystals with the same morphology. X-ray diffraction, scanning electron microscopy, transmission electron microscopy, and photoluminescence (PL) spectra as well as kinetic decays were used to characterize the samples. The pH values of microemulsion play an important role in the morphological control of the as-formed In(OH)3 nano-microstructures from the hydrothermal process. The formation mechanisms for the In(OH)3 nano-microstructures have been proposed on an aggregation mechanism. In2O3 nanorod bundles and spheres show a similar blue emission peaking around 416 and 439 nm under the 383-nm UV excitation, which is mainly attributed to the oxygen vacancies in the In2O3 nano-microstructures.     

Preparation of nanometer-sized In2O3 particles by a reverse microemulsion method

Nanometer-sized indium oxide (In(2)O(3)) particles have been prepared by chemical reaction of inorganic indium compounds and ammonia gas in a reverse microemulsion system consisting of water, Triton X-100 (surfactant), n-heptanol (co-surfactant), and n-octane (oil). Precursor hydroxides precipitated in the droplets of water-in-oil (W/O) microemulsion were calcined at different temperatures to form indium oxide powder. The factors affecting the particle size have been discussed; the calcination temperature is considered to be the important factor for controlling the size. In(2)O(3) calcined at 400 degrees C had a spherical form and a narrow size distribution. Calcination at 800 degrees C led to the formation of particles not only of irregular shape, but also of a wide size distribution. With the increase in calcination temperature from 400 to 800 degrees C, the average size of the particles grew from 7 to about 40 nm. The species of reactants used in the aqueous phase had a significant effect on the size of the particles. The average diameter of In(2)O(3) particles derived from reactant InCl(3) was 7 nm; that of particles derived from In(NO(3))(3) was 15 nm. The In(2)O(3) nanoparticles were characterized by transmission electron microscopy and X-ray diffraction. The phase behavior of the microemulsions is discussed.     

常压水热法合成玉米棒状In_2O_3及其性能研究

以In(NO_3)_3·4.5H_2O和(NH_2)_2CO为原料,采用常压水热法于95℃反应22 h制得氧化铟(In_2O_3)前驱物氢氧化铟,于600℃煅烧2 h合成了In_2O_3粉体,其结构、形貌及性能经紫外-可见(UV-Vis)光谱、X-射线衍射(XRD)、拉曼光谱和扫描电镜(SEM)表征。以甲基橙为目标降解物,研究了In_2O_3粉体的光催化活性。结果表明:In_2O_3粉体为体心立方晶系方铁锰矿结构和亚稳相刚玉六方结构的混合体,In_2O_3的UV-Vis谱图中出现了明显的蓝移。当In(NO_3)_3·4.5H_2O和(NH_2)_2CO物质的量比为1∶7时,In_2O_3粉体中出现了玉米棒状结构,棒状体长度约为500 nm,直径约150 nm;该棒状结构的In_2O_3对甲基橙有较好的光催化活性,在紫外光照射6.5 h后甲基橙的降解率为69.7%。     

Ambient pressure syntheses of size-controlled corundum-type In2O3 nanocubes

Hydrolysis of In(O-iPr)3 by 10 molar excess of water at 90 degrees C in a surfactant/solvent mixture of oleylamine/oleic acid/trioctylamine provides very small nanoparticles (<5 nm in diameter) of In(O)(OH). Subsequent in situ thermolysis of the formed In(O)(OH) nanoparticles at 350 degrees C and ambient pressure produces monodisperse h-In2O3 nanocubes, which can form an extended two-dimensional array on a flat surface. The size of the In2O3 nanocubes (8, 10, and 12 nm) could be easily controlled by the simple change in the amounts of employed surfactants. The h-In2O3 nanocube samples show blue PL emissions at room temperature due to, presumably, systematic oxygen vacancy.     

微波固相合成氧化锌纳米棒

通过前驱体的微波固相热分解法快速合成了氧化锌纳米棒, 其直径在60～385 nm之间, 长可达数微米. 前驱体则通过一步室温固相反应制备. 用X射线衍射仪(XRD)、扫描电子显微镜(SEM)、能量色散X射线分析(EDX)和透射电子显微镜(TEM)对产物的结构和形貌进行了表征. 同时, 对氧化锌纳米棒的光致发光(PL)性能作了测试, 结果表明在355 nm处有一个明显的近带隙发射峰. 另外, 对比实验表明, 微波辐射在氧化锌纳米棒的形成过程中起了关键性作用, 并对其形成机理进行了初步探讨.     

立方形貌ITO粉体的水热法制备及光电性能

以金属In和SnCl_4·5H_2O为原料,采用水热法在120~140℃得到In(OH)_3前驱体,该前驱体在550℃下煅烧得到立方体形貌的氧化铟锡粉体.研究了水热反应温度和反应时间对粉体形貌和晶型的影响.通过热分析仪(TG-DSC)、X射线衍射仪(XRD)、拉曼光谱仪(Raman)、透射电子显微镜(TEM)、四探针电阻仪、X射线光电子能谱仪(XPS)、紫外-可见-近红外分光光度计以及荧光光谱仪对粉体进行了表征,并对水热反应条件为140℃及12 h下制备的c-ITO的光电性能进行了分析.结果表明,随着水热反应温度的升高,ITO粉体形貌由立方体向不规则形貌转变,粉体晶型出现少量的六方相.在水热反应条件为140℃,12 h,铟离子与尿素的摩尔比为1∶5时,得到平均粒径为230 nm的立方体ITO粉体,其电阻率为1.247Ω·cm,光学能带间隙为3.685 e V,与c-In2O3相比其能带间隙更高,室温下260 nm激发波长下粉体出现光致发光,发射峰位于蓝光区域.     

Synthesis, characterization, and optical properties of In2O3 semiconductor nanowires

In2O3 semiconductor nanowires were synthesized by the chemical vapor deposition method through carbon thermal reduction at 900 degrees C with 95% Ar and 5% O2 gas flow. The In2O3 nanowires were characterized by field emission scanning electron microscopy (FE-SEM), high-resolution transmission electron microscopy (HRTEM), and photoluminescence spectroscopy (PL). For the first time, we observed the formation of corundum-type h-In2O3 nanowires and branched In2O3 nanowires. The PL spectra of In2O3 nanowires show strong visible red emission at 1.85 eV (670 nm) at low temperature, possibly caused by a small amount of oxygen vacancies in the nanowire crystal structure.     

Urea-based hydrothermal growth, optical and photocatalytic properties of single-crystalline In(OH)3 nanocubes

Nearly monodisperse single-crystalline In(OH)(3) nanocubes were successfully synthesized using In(NO(3))(3) x 4.5 H(2)O as indium source in the presence of urea and cetyltrimethyl ammonium bromide (CTAB) by a two-step hydrothermal process: the stock solution was heated at 70 degrees C for 24 h and then at 120 degrees C for 12 h. The structure and morphology of the resultant In(OH)(3) samples were determined by X-ray powder diffraction (XRD), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). The results revealed that most of as-synthesized In(OH)(3) nanocubes were uniform in size, with the average edge length of approximately 700 nm. The influences of the reaction temperature, the reaction time, the mineralizer, and the surfactant on the morphology of the obtained products were discussed in detail. Room-temperature photoluminescence (PL) spectrum of the In(OH)(3) nanocubes showed a peculiar strong emission peak centered at 480 nm. Furthermore, the photocatalytic properties of the In(OH)(3) nanocubes were tested. It was found that In(OH)(3) exhibited not only higher activity for benzene removal, but also better H(2) evolution from water than the commercial Degussa P25 TiO(2).     

In2O3/CdO复合材料的制备及气敏特性

采用水热合成方法制备了花状In2O3纳米材料.利用X射线衍射(XRD)、扫描电镜(SEM)、能量色散X射线光谱(EDX)及透射电镜(TEM)对材料的结晶学特性及微结构进行了表征.制备的In2O3材料呈现花状,是由粒径约20nm的椭球状小颗粒构成的分级结构材料.将制备的In2O3与纳米CdO以摩尔比1:1混合后,发现制成的In2O3/CdO复合材料经热处理后呈现葡萄状多孔结构.测试In2O3/CdO复合材料制作的气敏元件处于最佳工作温度(410°C)时,对0.05×10-6(体积分数,φ)的甲醛气体表现出较高的灵敏度.对比测试发现,In2O3/CdO复合材料制作的气敏元件对不同浓度甲醛的灵敏度明显优于纯花状In2O3纳米材料.同时In2O3/CdO复合材料制作的气敏元件在乙醇、甲苯、丙酮、甲醇以及氨气等干扰气体中具有对甲醛良好的选择性.讨论了In2O3/CdO复合材料气敏元件的敏感机理.     

Aerosol assisted chemical vapor deposition of In2O3 films from Me3In and donor functionalized alcohols

The reaction of Me3In and ROH (R = CH2CH2NMe2, CH(CH3)CH2NMe2, C(CH3)2CH2OMe, CH2CH2OMe) in toluene under aerosol assisted chemical vapor deposition (AACVD) conditions leads to the production of indium oxide thin films on glass. The indium oxide films were deposited at 550 degrees C and analyzed by scanning electron microscopy (SEM), X-ray powder diffraction, wavelength dispersive analysis of X-rays (WDX), X-ray photoelectron spectroscopy (XPS), and Raman spectroscopy. This CVD technique offers a rapid, convenient route to In2O3, which presumably involves the in situ formation of dimethylindium alkoxides, of the type [Me2InOR]2. In order to identify compounds present in the aerosol mist, the solution-phase reaction between Me3In and ROH (R = CH2CH2NMe2, C(CH3)2CH2OMe, CH(CH3)CH2NMe2, CH(CH2NMe2)2) at room temperature in toluene was carried out. Dimeric indium alkoxides, of the type [Me2In(OR)]2, were isolated, and their structures were determined by X-ray crystallography.