纳米SnO2的水热合成

以ＳｎＣｌ４．５Ｈ２Ｏ为原料，用水热法制备了粒度均匀的纳米ＳｎＯ２微粉，研究了反应温度，介质的酸度和反应物浓度等因素对ＳｎＯ２微晶形成，粒子尺寸及产率的影响。Ｘ射线物相分析表明，在酸性介质中，不同温度（１２０～２２０℃）下所形成的产物都是四方晶系ＳｎＯ２，适当降低反应介质的酸度有得于ＳｎＯ２粒子尺寸的减小和产率的提高，随反应温度升高，ＳｎＯ２粒子逐渐长大，当ｐＨ＝１．４５时，粒子的平均尺寸由大约２     

掺镁钛酸钡纳米棒的水热合成和光催化性能

用水热法制备掺镁钛酸钡(Ba1-xMgxTiO3(x=0,0.10,0.20,0.30,0.40),BMT)纳米粉体。运用X射线衍射仪(XRD)、场发射扫描电子显微镜(FESEM)、透射电子显微镜(TEM)、紫外可见漫反射光谱技术(DRS)等手段对样品进行了表征,并在可见光照射下于溶液中考察了其光催化降解甲基橙反应活性。结果表明,通过控制氢氧根浓度可以得到不同形貌的纳米粉体。基于不同条件下制备的样品的微结构分析,提出了这些不同形貌的形成机制。制备出的BMT材料的带隙能约为2.61 eV。光催化反应结果表明BMT的光催化活性比掺氮TiO2高得多。OH-浓度为8 mol·L-1时制备的BMT纳米棒光催化效率最高,经可见光照射360 min,浓度为0.01 mmol·L-1甲基橙溶液的降解率可达到93.0%,且循环使用4次后,其光催化活性并没有明显降低,表明BMT是一种稳定有效的可见光催化剂.     

球形SnO2 纳米微粒的合成及形成机理分析

以SnCl4*5H2O为主要原料,用溶剂热技术在油酸体系中成功地合成了球形SnO2纳米微粒,在无水乙醇体系中合成了菱形的SnO2纳米微粒.通过X射线粉末衍射(XRD),选区电子衍射(SAED)和透射电镜(TEM)对两种产物进行了表征,并对两种产物的形成机理进行了分析.透射电镜(TEM)结果表明: 在油酸体系中得到了平均尺寸约为 3.5 nm的球形SnO2纳米微粒,此微粒趋向于特殊高的比表面积,适合于作气敏探测器材料方面的应用.     

水热合成法对纳米氧化锡粉体粒径和形貌的控制研究

利用氯化锡和氨水作为反应试剂,通过水热合成技术制备了近球形,棒状,椭球形,六角形等粉体形貌和粒径范围从4 nm至120 nm的纳米氧化锡粉体,并对水热合成条件对粉体的粒径和形貌的影响进行了研究。所制备的粉体的XRD分析结果显示,合成温度在160 ℃以上并且合成时间在3 h以上,粉体全部具有氧化锡晶体结构。利用透射电镜对粉体的粒径和形貌观察发现,二氧化锡粉体的形貌和粒径可通过改变溶液的浓度,合成温度与合成时间进行有效的控制,其中合成温度与溶液浓度不仅可以控制合成粉体的粒径,而且可以控制粉体的形貌。     

Na2SO4辅助水热合成SnO2纳米晶

系统地研究了以SnCl₄·5H₂O为原料，以Na₂SO₄为矿化剂，采用水热法在较低温度下和较短的反应时间内制备结晶良好并均匀分散的SnO₂纳米晶。采用X射线衍射(XRD)、透射电子显微镜(TEM)、红外光谱(IR)等技术对水热反应的晶化过程进行了分析。结果表明：在Na₂SO₄存在的情况下，在120 ℃反应4 h 即可制备得到晶粒细小，分散性能良好的SnO₂纳米晶。XRD衍射峰峰宽随水热温度的升高或反应时间的延长而变窄，结晶性提高。TEM结果表明产物颗粒小、分散性能良好。水热反应温度和反应时间对产物结晶度和粒径有明显的影响。对Na₂SO₄在反应过程中的作用机理进行了分析。     

SnO2纳米晶的水热合成及其气敏特性

SnO2 nanocrystal with different crystalline sizes were prepared with SnCl2 2H2O and H2O2 raw materials by a hydrothermal process. The synthesized powders at different reaction temperatures were characterized by means of powder X-ray diffraction, transmission electron microscope, specific surface area and gas sensitivity measurements. The results revealed that the pure SnO2 nanocrystallites synthesized at 120 ℃ have high specific surface area （210.3 m2/g）, and show a high sensitivity to C2H5OH gas. Both traits are beneficial in gas-sensitive detection application.     

超细钛酸钡粉体的水热合成

以偏钛酸和氢氧化钡为原料,用水热反应制备了超细钛酸钡粉体,其结构经XRD和-IEM表征。粒径60nm-100nm。较佳的反应条件为：偏钛酸20mmol,n(Ba)：n(Ti)=1．2,于240℃反应8h,加入少量异丙醇可明显改善粉体的分散性能。     

纳米晶钛镧酸盐的水热合成和表征

报道了在TiO₂-La₂O₃-M₂O-H₂O水热体系中,新型钛镧酸盐M_0.5La_0.5TiO₃(M=La,Ag_0.66Na_0.33,Li_0.6Na_0.4)的水热合成,用XRD、SEM、TEM、ICP、DTA-TG、IR和ac阻抗分析技术进行了结构表征.讨论了水热合成反应体系pH、反应混合物的组成比以及晶化温度等因素对合成的影响.XRD分析表明,Na_0.5La_0.5TiO₃和Ag_0.33Na_0.17La_0.5TiO₃具有立方结构,晶胞参数分别为a=0.3877nm和a=0.3890nm.Li_0.3Na_0.2La_0.5TiO₃具有正交结构,a=0.3894nm,b=0.3912nm,c=0.3890nm.TEM测定显示Na_0.5La_0.5TiO₃和Ag_0.33Na_0.17La_0.5TiO₃是纳米尺度晶体,平均粒度分别为50nm和70nm.Li_0.3Na_0.2La_0.5TiO₃的平均粒度分布为5Lm.Ag_0.33Na_0.17La_0.5TiO₃在440℃的电导率为1.9×10^-5S/cm,Li_0.3Na_0.2La_0.5TiO₃的电导率为1.5×10^-6S/cm.     

ZnS微米球的水热合成及光催化性能研究

以L-半胱氨酸为硫源,明胶作为组装剂,采用水热方法制备了粒径均一的ZnS微米球。利用XRD,TEM,FESEM,FTIR探讨了明胶、反应时间和反应温度对产物形貌和尺寸的影响,其结果表明ZnS微米球是由ZnS纳米颗粒组装而成的3D多级结构。光催化性能研究表明,明胶的加入提高了最终产物的光催化性能。利用产物的荧光发光性能解释了其光催化性能产生差异的原因。     

锑掺杂二氧化锡(ATO)纳米颗粒:共沸蒸馏干燥法制备及隔热性能

以五水合四氯化锡、三氯化锑为原料,乙醇为溶剂,氨水为沉淀剂,乙酸异戊酯为共沸溶剂,共沸蒸馏干燥前驱体溶胶,650℃煅烧后制备了单分散不同锑掺杂量的掺锑二氧化锡(ATO)纳米颗粒。结果表明,锑含量对颗粒粒径、光电性质具有重要影响,10mol%锑掺杂量时,样品具有最低的电阻率以及最优良的光学性质(最高的可见光透过率与近红外屏蔽效果),电学性质。ATO与聚氨酯复合涂膜玻璃隔热测试表明,涂层薄膜具有优良的隔热效果,能够有效地减小热量的传递与扩散。     

Controlled synthesis of monodisperse sub-100 nm hollow SnO2 nanospheres: a template- and surfactant-free solution-phase route, the growth mechanism, optical properties, and application as a photocatalyst

Controlled synthesis of low‐dimensional materials, such as nanoparticles, nanorods, and hollow nanospheres, is vitally important for achieving desired properties and fabricating functional devices. We report a systematic investigation of the growth of low‐dimensional sub‐100 nm SnO₂ hollow nanostructures by a mild template‐ and surfactant‐free hydrothermal route, aiming to achieve precise control of morphology and size. The starting materials are potassium stannate and urea in an ethylene glycol (EG)/H₂O system. We found the size of the SnO₂ hollow nanospheres can be controlled by simply adjusting the urea concentration. Investigation of the mechanism of formation of the SnO₂ hollow nanospheres revealed that reaction time, urea concentration, and reaction temperature make significant contributions to the growth of hollow nanospheres. On switching the solvent from EG/H₂O to H₂O or ethanol, the SnO₂ nanostructures changed from nanospheres to ultrafine nanorods and nanoparticles. On the basis of reaction parameter dependent experiments, oriented self‐assembly and subsequent evacuation through Ostwald ripening are proposed to explain the formation of hollow nanostructures. Their size‐dependent optical properties, including UV/Vis absorption spectra and room‐temperature fluorescence spectra, were also studied. Moreover, the studies on the photocatalytic property demonstrate that the fabricated hollow structures have slightly enhanced photocatalytic degradation activity for rhodamine B when exposed to mercury light irradiation compared to solid SnO₂ nanospheres under the same conditions. The synthesized tin oxide nanoparticles display high photocatalytic efficiency and have potential applications for cleaning polluted water in the textile industry.     

三维钒氧化合物的水热合成与表征

利用水热合成的方法,制备了三维钒氧化合物H3V3O9,X射线衍射实验确定了其结构,结果显示,晶体为单斜晶系,P1空间群,晶胞参数为a=4.9980(10)nm,b=8.4188(17)nm,c=7.8614(16)nm,α=90.00°,β=96.40(3)°,γ=90.00°,Z=328.72(11),D=2.999,F(000)=282,R1=0.023 0,wR2=0.0678.通过IR光谱和热重分析对化合物进行了表征.     

Hydrothermal synthesis, structure and photocatalytic property of nano-TiO_2-MnO_2

TiCI4 and MnSO4.H2O as raw materials are hydrolyzed stiochiometrically, following the intermediate of oxide hydrating reacts at 150℃, 0.5 MPa in high-pressure reactor, after filtering, washing and drying, nanometric TiO2-MnO2 (Ti1-xMnxO2) is prepared. The effects of the reaction temperature and time on nanometric TiO2-MnO2 are also discussed. XRD shows that the product is TiO2-MnO2 with amorphous phase. After being sintered at above 780℃, it transfers into Ti1-xMnxO2 with a rutile structure. TEM shows that TiO2-MnO2 is the spherical particle. And the average diameter of the particles is 20 nm. The optical absorbance was determined by UV-265 spec-trophotometer after dispersing the sample in the mixture of water and glycerol with the ratio of 1 : 1 equably. It is found that the nano-material possesses the advantages of both nano-TiO2 and nano-MnO2, and it has strong absorption in the UV and visible region. Photodegradation of dyes in an aqueous solution is investigated using nanometricTiO2-MnO2 as a pho     

Sb掺杂SnO_2(ATO)纳米晶的水热合成和导电性能

以Sn和SbI_3为主要原料，在120-170 ℃温和水热条件下合成了具有导电能力 的Sb掺杂SnO_2(ATO)透明导电纳米粉体，运用FT-IR， XRD， BET， TEM等手段对 粉体的形成过程进行了分析表征。实验结果表明，所合成的纳米ATO粉体均为四方 锡石结构，无其他杂相存在，晶粒大小在4-7nm之间，粉体呈单分散状态。比表面 积在137-184m~2·g~(-1)之间，随水热温度的升高，晶粒长大，比表面积下降，粉 体导电性能提高。该方法对于其他透明导电氧化物纳米粉体的合成具有借鉴意义。     

SnO2纳米微晶的合成及气敏性分析

采用溶剂热技术分别在油酸体系及无水乙醇体系中成功地合成了球形和菱形的 Sn O2 纳米微晶。通过X-射线粉末衍射、选区电子衍射、透射电镜和比表面积测定等手段对合成产物的结构进行了表征 ,并对合成产物的气敏性进行了分析。结果表明 :含有精细结构的球形 Sn O2 纳米微晶的比表面积为 1 4 6 m2· g-1,灵敏温度为 1 6 0℃左右 ,适合于作气敏元件材料     

从不同氧化态锡盐水热合成法制备纳米SnO2粉体

Nanocrystalline SnO₂ were prepared by a novel gel hydrothermal route from alcoholic solutions of tin(Ⅱ) and tin(Ⅳ) salts. X-ray diffraction analysis and transmission electron microscopy showed that the resulting oxides were both in the form of powders having crystallites of about 5 nm in diameter. The formation procedures of the two precursors and the gas-sensing properties of the two SnO₂ nanocrystals were compared.     

Hydrothermal synthesis, structure and property of nano-BaTiO_3based dielectric materials

A series of Ba1-xSrxTi1-yZryO3 (0≤x≤0.5, 0≤y≤0.4) and Ba1-xZnxTi1-ySnyO3 (0≤x≤0.3, 0≤y≤0.3) solid solutions were synthesized by low-temperature/low-pressure hydrothermal method below 170℃, 0.8 MPa. XRD pattern and cell parameters-composition figures of these prepared powders demonstrated that they are completely miscible solid solutions based on BaTiO3. Furthermore, TEM showed that they have a shape of uniform, substantially spherical particles with an average particle size of 70 nm in diameter. The sintered ceramics of those powders doped by Sr2+ and Zr4+ or Zn2+ and Sn4+ have dielectric constant twelve times higher than and dielectric loss 1/6 those of pure BaTiO3 phase at room temperature.