氧化锌空心微球的制备及其催化性能

以乙二醇为溶剂,聚乙二醇-10000为表面活性剂,硝酸锌和醋酸钠为原料,利用溶剂热法,合成了氧化锌空心微球。并用X射线衍射、扫描电子显微镜、热重、比表面和孔径分布等对其进行了表征。考察了硝酸锌用量、聚乙二醇-10000用量、反应时间和反应温度等对氧化锌空心微球形貌和大小的影响。考察了氧化锌空心微球催化分解高氯酸铵的性能,结果表明,由于氧化锌空心微球的加入,高氯酸铵的分解温度由442℃降低至280℃左右。     

不规则形ZnO纳米棒的制备及其光催化性能研究

本文采用溶剂热法,以Zn(NO3)2,NaAc为原料,聚乙二醇-10000为表面活性剂,制备了不规则形的ZnO纳米棒。并用X-射线衍射仪(XRD)、扫描电镜(SEM)、透射电镜(TEM)、荧光光谱、紫外-可见分光光度计对其进行了表征。考察了硝酸锌用量、聚乙二醇-10000用量、反应时间和反应温度等对氧化锌粒子形貌和大小的影响,初步讨论了氧化锌纳米棒的可能形成机理。以ZnO纳米棒作为光催化剂,考察了其光催化降解龙胆紫的性能。研究了催化剂用量、龙胆紫的初始浓度对光催化降解率的影响。     

溶剂热合成Cu2O微球及其对高氯酸铵热分解的催化作用

以聚乙烯吡咯烷酮(PVP)为添加剂,利用溶剂热法合成了Cu2O微球.考察了PVP用量以及反应温度对产物形貌的影响,并在反应时间为2.5与4.5h时分别合成了直径为100-200nm和1μm的Cu2O微球.同时,利用差热分析(DTA)技术考察了不同直径的Cu2O微球对高氯酸铵(AP)热分解的催化效果,结果表明:添加2%(w)的直径为100-200nm和1μm的Cu2O微球使得AP的高温分解温度分别降低了116和118°C,AP在低温阶段的分解量也明显提高.     

酵母模板合成CuO空心微球及其催化性能研究

以酵母作为生物模板合成了氧化铜空心微球。X-射线粉末衍射、电子扫描电镜、氮气吸附-脱附、紫外-可见光漫反射光谱对产品的物化结构和性能进行了表征。电子扫描电镜分析表明氧化铜产物具有空心结构,粒径为2.2-2.9μm。X射线粉末衍射表明CuO空心微球具有很好的单斜晶型结构。氮气吸附-脱附表明CuO空心微球的比表面积是8.15 m2/g,壳体表面具有多孔性,中孔尺寸分布在2.0-35.4 nm。紫外-可见光漫反射光谱证实产物的能隙是1.38 ev。傅里叶红外、热重-差热以及X射线能谱分析监控了合成过程中组分及化学键的变化,据此提出了空心氧化铜的合成机理。进一步利用差热分析,研究了空心氧化铜催化热分解高氯酸铵的反应,证实了该空心氧化铜产品具有很高的催化活性。     

溶剂热法制备硫化镍空心微球

以醋酸镍和硫代乙酰胺为原料, 乙醇为溶剂, 在150 ℃的溶剂热条件下制备了硫化镍空心微球, 并用XRD, TEM, SAED和SEM对产物进行了表征. 结果显示, 这些空心微球由β-NiS和α-NiS组成, 从反应开始得到的α-NiS实心球通过内核的消溶演变而成.     

纳米LaCoO3的制备及其对高氯酸铵分解的催化性能

以硝酸镧和硝酸钴为原料,通过硬脂酸法制备了纳米LaCoO3。采用红外光谱、X射线衍射、透射电镜等测试手段对产物进行了表征,并用热分析法考察了不同含量的纳米LaCoO3对高氯酸铵热分解的催化作用。结果表明,在600℃下可获得结晶良好的钙钛矿型纳米LaCoO3,粒径约40-60 nm。纳米LaCoO3能强烈催化高氯酸铵的热分解,催化作用随着LaCoO3含量的增加而增强。添加5%的纳米LaCoO3可使高氯酸铵的高温分解温度下降116℃,分解放热量也由2%时的1390 J·g^-1增至1600 J·g^-1。     

纳米CuO：不同形貌的制备及对高氯酸铵热分解催化性能

采用超声法和微波水热法,制备了棒状、球状、梭形和杨桃状纳米CuO粉体。以X-射线粉末衍射仪(XRD)、透射电镜(TEM)手段对各种产物进行了表征。用热分析法考察了不同形貌的纳米CuO对高氯酸铵(AP)分解的催化作用。结果表明,四种形貌的纳米CuO均可强烈催化AP的热分解,而棒状和球状纳米CuO的催化活性更高。与纯高氯酸铵相比,加入棒状纳米CuO后AP的高温分解温度降低了124.4 ℃,加入球形纳米CuO催化剂后高温分解温度降低了122 ℃,且低温分解峰消失。     

Au@ZrO_2空心纳米微球的制备及其催化性质

以Stober法合成了不同粒径的SiO_2微球。以这些SiO_2微球为硬模板,通过ZrOCl_2前驱体吸附和水解制备得到了ZrO_2@SiO_2复合物,然后用HF溶解去除二氧化硅模板剂,制备得到ZrO_2空心球。以ZrO_2空心球为载体,采用沉积-沉淀法(DP)合成了Au@ZrO_2纳米空心微球。考察了Au@ZrO_2纳米空心微球在对硝基苯胺还原反应中的催化性能。研究结果表明,所合成的SiO_2微球粒径大小均一、形状规则、分散性好;ZrO_2空心微球大小及比表面积可以通过硬模板SiO_2微球粒径进行有效控制;与Au@ZrO_2实心微球相比,Au@ZrO_2空心微球在对硝基苯胺还原反应中表现出良好的催化性能,当反应温度为45℃、反应7 min时,对硝基苯胺能够完全转化为对苯二胺。     

以聚乙二醇为模板剂制备MoS2空心微球

以聚乙二醇(PEG)为模板剂, 采用软模板法制备出MoS2空心微球, 并采用X射线衍射仪(XRD)、红外光谱仪(IR)和扫描电子显微镜(SEM)对产物进行表征. 结果表明, 所制备的MoS2为粒径约2-7 μm的空心微球, 但结晶程度较差, 需通过退火工艺进行改善; 聚乙二醇与MoS2发生了较为强烈的有机-无机杂化作用, 其浓度和分子量对产物形貌调控均有重要影响. 同时, 结合红外光谱分析, 对MoS2空心微球的形成机理进行了初步的探讨.     

以聚乙二醇为模板剂制备MoS2空心微球

以聚乙二醇(PEG)为模板剂,采用软模板法制备出MoS2空心微球,并采用X射线衍射仪(XRD)、红外光谱仪(IR)和扫描电子显微镜(SEM)对产物进行表征.结果表明,所制备的MoS2为粒径约2-7μm的空心微球,但结晶程度较差,需通过退火工艺进行改善;聚乙二醇与MoS2发生了较为强烈的有机-无机杂化作用,其浓度和分子量对产物形貌调控均有重要影响.同时,结合红外光谱分析,对MoS2空心微球的形成机理进行了初步的探讨.     

ZnO twin-cones: synthesis, photoluminescence, and catalytic decomposition of ammonium perchlorate

ZnO twin-cones, a new member to the ZnO family, were prepared directly by a solvothermal method using a mixed solution of zinc nitrate and ethanol. The reaction and growth mechanisms of ZnO twin-cones were investigated by X-ray diffraction, UV-visible spectra, infrared and ion trap mass spectra, and transmission electron microscopy. All as-prepared ZnO cones consisted of tiny single crystals with lengths of several micrometers. With prolonging of the reaction time from 1.5 h to 7 days, the twin-cone shape did not change at all, while the lattice parameters increased slightly and the emission peak of photoluminescence shifted from the green region to the near orange region. ZnO twin-cones are also explored as an additive to promote the thermal decomposition of ammonium perchlorate. The variations of photoluminescence spectra and catalytic roles in ammonium perchlorate decomposition were discussed in terms of the defect structure of ZnO twin-cones.     

不同形貌纳米氧化锌的水热法合成

以氯化锌为锌源,以氢氧化钠为碱源,采用水热法合成了不同形貌的纳米氧化锌;探讨了晶化时间、晶化温度、表面活性剂十六烷基三甲基溴化铵(CTAB)对纳米ZnO形貌的影响.结果表明:不添加CTAB时,在120℃下反应24h得到的纳米氧化锌为颗粒状,而在160℃下反应24h得到的纳米氧化锌为片状.当添加CTAB后,在120℃可得到片状氧化锌,而在160℃可得到颗粒状氧化锌.     

O/W/O double emulsion-assisted synthesis and catalytic properties of CeO2 hollow microspheres

CeO₂ hollow microspheres have been fabricated through a simple thermal decomposition of precursor approach. The precursor with an average size of 10 μm was prepared in a reverse microemulsions containing Ce(NO₃)₃·6H₂O and CO(NH₂)₂ at 160 °C. The products were characterized by X-ray powder diffraction (XRD), transmission electron microscope (TEM), selected area electron diffraction (SAED) and scanning electron microscopy (SEM). The possible formation mechanism of hollow spheres was discussed. In addition, the CeO₂ hollow microspheres modified glassy carbon electrode exhibit excellent sensing performance towards methyl orange, which provide a new application of CeO₂ hollow spheres. The catalytic activity of CeO₂ hollow spheres on the thermal decomposition of ammonium perchlorate (AP) also was investigated by TGA. The catalytic performance of CeO₂ hollow spheres is superior to that of commercial CeO₂ powder.     

MOF-derived hollow NiO–ZnO composite micropolyhedra and their application in catalytic thermal decomposition of ammonium perchlorate

Ni(II)-doped Zn-based coordination polymer particles (Ni(II)-doped Zn-CPPs) with controllable shape and size were successfully synthesized by solvothermal method, which further transformed to porous ZnO–NiO composite micropolyhedra without significant alterations in shape by calcination in air. Those products were characterized by powder X-ray diffraction (XRD), field emission scanning electron microscopy (SEM), transmission electron microscopy (TEM), thermogravimetric analysis (TGA), infrared spectroscopy (IR) and gas adsorption measurements. The catalytic activity of ZnO–NiO composites for the thermal decomposition of ammonium perchlorate (AP) was investigated. The result shows that all ZnO–NiO composites efficiently catalyzed the thermal decomposition of AP, and NiO–ZnO composite hollow octahedrons have the highest catalytic efficiency compared with that of most materials reported to now, indicating that porous ZnO–NiO composite micropolyhedra could be a promising candidate material for application in AP-based propellant.     

焙烧温度对ZnO粉体结晶及光学性能的影响

以草酸铵和醋酸锌为原料,采用直接沉淀法制备ZnO粉体,考察了焙烧温度对粉体结晶和光学性能的影响。 采用热重分析（TGA-DTA）、X射线衍射、紫外-可见漫反射（UV-Vis）、荧光分光光度计（FS）和扫描电子显微镜（SEM）等方法对样品进行了分析。 结果表明,制备的前驱物为C2O4Zn·2H2O,最低焙烧温度400 ℃,随着焙烧温度的提高,粉体结晶度提高,一次粒径增大;600 ℃焙烧后有较强紫外发光峰,粉体由200 nm的粒子排列成层叠状;900 ℃焙烧后有较强可见发光峰,粉体粒子大于500 nm,团聚严重;粉体有较强的紫外吸收,吸收峰有蓝移。     

NiO纳米片和多孔纳米片自组装的空心微球的无模板水热法制备与磁学性质

报道一种非常简单的制备NiO和Ni(OH)₂空心微球的无模板水热法, 即通过NiCl₂与氨水在140 ℃水热反应12 h, 制备了Ni(OH)₂纳米片自组装的空心微球, 经400 ℃热处理2 h得到了NiO空心微球. 采用X射线衍射仪、扫描电镜和透射电子显微镜对产物进行表征, 并在室温下测试了它的磁学性能, 结果表明, Ni(OH)₂空心微球的直径约为3～4 μm, 它是由尺寸1.1～1.3 μm左右的六方相结构的Ni(OH)₂纳米片组装而成; NiO空心微球是由立方相纳米片和多孔纳米片组装而成, 它具有弱的铁磁性, 其矫顽力为583 Oe, 剩余磁化强度为0.213 emu/g. 研究了氨在Ni(OH)₂纳米片的形成与组装过程中的作用, 提出了可能的生长机理.     

ZnO-based hollow microspheres: biopolymer-assisted assemblies from ZnO nanorods

Many efforts have been made in fabricating three-dimensional (3D) ordered zinc oxide (ZnO) nanostructures due to their growing applications in separations, sensors, catalysis, bioscience, and photonics. Here, we developed a new synthetic route to 3D ZnO-based hollow microspheres by a facile solution-based method through a water-soluble biopolymer (sodium alginate) assisted assembly from ZnO nanorods. The products were characterized by X-ray diffraction, field emission scanning electron microscopy, transmission electron microscopy, selected area electron diffraction, and X-ray photoelectron spectroscopy. Raman and photoluminescence spectra of the ZnO-based hollow microspheres were obtained at room temperature to investigate their optical properties. The hollow microspheres exhibit exciting emission features with a wide band covering nearly all the visible region. The calculated CIE (Commission Internationale d'Eclairage) coordinates are 0.24 and 0.31, which fall at the edge of the white region (the 1931 CIE diagram). A possible growth mechanism of the 3D ZnO superstructures based on typical biopolymer-crystal interactions in aqueous solution is tentatively proposed, which might be really interesting because of the participation of the biopolymer. The results show that this biopolymer-directed crystal growth and mediated self-assembly of nanocrystals may provide promising routes to rational synthesis of various ordered inorganic and inorganic-organic hybrid materials with complex form and structural specialization.     

Clewlike ZnV2O4 Hollow Spheres: Nonaqueous Sol–Gel Synthesis,Formation Mechanism,and Lithium Storage Properties

Hollow ZnV₂O₄ microspheres with a clewlike feature were synthesized by reacting zinc nitrate hexahydrate and ammonium metavanadate in benzyl alcohol at 180 °C for the first time. GC–MS analysis revealed that the organic reactions that occurred in this study were rather different from those in benzyl alcohol based nonaqueous sol–gel systems with metal alkoxides, acetylacetonates, and acetates as the precursors. Time‐dependent experiments revealed that the growth mechanism of the clewlike ZnV₂O₄ hollow microspheres might involve a unique multistep pathway. First, the generation and self‐assembly of ZnO nanosheets into metastable hierarchical microspheres as well as the generation of VO₂ particles took place quickly. Then, clewlike ZnV₂O₄ hollow spheres were gradually produced by means of a repeating reaction–dissolution (RD) process. In this process, the outside ZnO nanosheets of hierarchical microspheres would first react with neighboring vanadium ions and benzyl alcohol and also serve as the secondary nucleation sites for the subsequently formed ZnV₂O₄ nanocrystals. With the reaction proceeding, the interior ZnO would dissolve and then spontaneously diffuse outwards to nucleate as ZnO nanocrystals on the preformed ZnV₂O₄ nanowires. These renascent ZnO nanocrystals would further react with VO₂ and benzyl alcohol, ultimately resulting in the final formation of a hollow spatial structure. The lithium storage ability of clewlike ZnV₂O₄ hollow microspheres was studied. When cycled at 50 mA g^?1 in the voltage range of 0.01–3 V, this peculiarly structured ZnV₂O₄ electrode delivered an initial reversible capacity of 548 mAh g^?1 and exhibited almost stable cycling performance to maintain a capacity of 524 mAh g^?1 over 50 cycles. This attractive lithium storage performance suggests that the resulting clewlike ZnV₂O₄ hollow spheres are promising for lithium‐ion batteries.