紫外线辐照制备单分散ZnS纳米颗粒

以硫代硫酸钠和乙酸锌为反应物、柠檬酸为调控剂,在紫外光辐照下制备出单分散的ZnS纳米颗粒。采用XRD、TEM、低温氮吸附-脱附、HRTEM和EDS等方法研究了反应物浓度、辐照时间和柠檬酸用量等因素对产物颗粒尺寸和分布的影响。结果表明,随着反应时间延长,产物收率增高,平均晶粒度增大,比表面积变小。反应物浓度对产物组成和比表面积有较大影响,但对产物的平均晶粒度影响不大。适量添加柠檬酸,有利于制备单分散的ZnS纳米颗粒。     

微乳液法制备CaF2纳米颗粒

目前 ,通过微乳液合成方法已成功地制备出许多种类的化合物纳米微粒[1,2 ] .Bender等[3] 曾用微乳液法制备出掺杂钕的 Ba F2 纳米颗粒 ,并研究了其荧光特性 ,样品的最大发射波长为 1 0 52 nm,荧光寿命为 3 50～ 90 0 ns,在适当的钕掺杂浓度下 ,获得了较高的荧光强度 .Qiu等[4 ] 也于微乳液体系中制备出 Ce F3纳米颗粒 .纳米复合体系 (Mg2 Si O4 ∶Cr)可以用作光放大材料[5] ,其光学增益可以与路径长度相当的单晶体相比拟 .基于掺杂稀土离子的氟化物纳米复合体系存在着巨大的应用前景 ,本文用微乳液技术首次制备出 Ca F2 纳米微粒 ,为研…     

纳米微粒的微乳液制备法

Ｗ／Ｏ微乳液制备纳米微粒是一新兴的研究领域。本文系统地介绍了乳浮液制备法的基本原理、微乳液“水池”中纳米微粒的鉴定方法、目前该领域的研究进展，并提出了适用于制备纳米微粒的微乳液体系的选择标准及该领域研究工作的展望。     

单分散磁性纳米颗粒的制备及生物高分子在其上的组装

磁性纳米颗粒因其潜在的生物医学应用价值而成为纳米生物材料领域研究的前沿。本文综述了单分散磁性纳米颗粒的制备方法以及生物高分子在磁性纳米颗粒上的组装的研究进展。     

紫外辐照法合成单分散钨酸纳米颗粒

通过紫外光照射柠檬酸钨氧配合物水溶液,制备了平均粒径约为20 nm的单分散钨酸纳米颗粒。红外光谱研究表明,柠檬酸钨氧配合物在紫外光照射下发生分解,形成柠檬酸和钨酸,而柠檬酸在钨酸的催化作用下发生光降解。XRD结果表明,单分散钨酸纳米颗粒是由WO₃·2H₂O和WO₃·H₂O组成的。此外,还考察了光照时间以及柠檬酸与钨酸钠的物质的量之比(n_cit/n_st)对产物结构和形貌的影响。随着光照时间延长,产物中WO₃·2H₂O的含量降低而WO₃·H₂O含量升高,产物粒径增大且分布加宽;随着n_cit/n_st增加,产物中WO₃·2H₂O含量增高,而WO₃·H₂O含量降低,且产物粒径变小而粒径分布变窄。     

微乳液体系中Ni-La-B非晶态合金纳米团簇的制备及退火晶化

ni-la-b非晶态合金;微乳液;纳米团簇;晶化;单分散     

微乳液法低温制备纳米金红石型二氧化钛的研究

以TiCl₄为原料、在十六烷基三甲基溴化铵/正己醇/水组成的微乳液体系中、在较低温度下,制备了球形、花状、捆绑丝和星形的金红石型二氧化钛纳米颗粒。研究了w值(水与CTAB物质的量之比)、反应物浓度、反应温度以及P值(正己醇与CTAB的物质的量之比)等因素对产品形貌的影响,并用TEM、XRD对产品进行了表征。     

单分散耐高温聚酰亚胺微球的制备及性能

聚酰亚胺(PI)微球因其微纳结构所赋予独特的物理化学性质而受到广泛的关注。本研究采用相反转乳化法实现对PI的微球化,制备的PI微球具有单分散特性。研究结果表明,PI分子结构中引入疏水基团有利于微球化,搅拌速度和乳化剂浓度影响PI微球的形貌及粒径分布。     

单分散共价有机框架纳米颗粒的室温快速制备

以稀土金属三氟甲磺酸盐作为新型的共价有机框架(COF)合成催化剂,成功制备了 4种不同结构的COF(COF-42、TPBDMTP、RT-COF-1、COF-LZU1)的单分散纳米级颗粒,并通过对反应条件的系统性调控,实现200～900 nm范围内精确控制COF的粒径。X射线衍射表征证明了产物良好的结晶性。此外,相较于传统的水热合成,该方法可在室温常压条件下操作,并且在0.5 h内快速得到产物。     

纳米氧化锌的微乳液法制备

纳米ZnO颗粒尺寸较小,比表面积较大,其粉体具有非常高的化学活性,表现出表面与界面效应、小尺寸效应、量子尺寸效应和宏观量子隧道效应.纳米ZnO在电、磁、光、热等方面具有一般ZnO所无法比拟的性能,广泛用于气体敏感材料、涂料和高效催化剂等许多领域.因而,制备高质量的纳米ZnO是非常重要的.     

稳定分散的纳米银溶胶的制备及其表征

Stable aqueous dispersive colloidal Ag nanoparticles were prepared by reducing silver nitrate with sodium borohydride in the presence of 3-mercaptopropionic acid. The formation process of the Ag nanoparticles was investigated by UV-Visible spectroscopy and transmission electron microscopy. The results show that the spherical and rodlike particles and aggregates are formed in the initial stage of the reaction， then the rodlike particles and aggregates are gradually decomposed into small spherical particles， and the final obtained Ag nanoparticles with an average size of 8 nm are in uniform shapes and narrow size distribution， and the colloid remains stable for more than one month， which makes it convenient for use in practice. The presence of capping agent plays an extra role over nanoparticles stabilization and morphology. The presence of capping agent on the surface of Ag nanoparticle is confirmed by the X-ray photoelectron spectroscopy. It is found that Ag nanoparticles are negatively charged in alkaline condition， whereas they are positively charged in acid condition. Electrosteric effect is responsible for their long-term stability.     

室温离子液体中银纳米微粒的制备与结构表征

利用化学还原方法在室温离子液体1-甲基-3-丁基咪唑四氟硼酸盐中制备了金属银纳米微粒,采用X射线衍射,透射电子显微镜,傅立叶红外光谱和热分析对所制备的样品进行了结构表征.结果表明,所制备的银纳米微粒具有立方相结构,粒径约为20 nm.离子液体不但作为反应的溶剂而且作为修饰剂修饰在银纳米微粒的表面,从而有效地阻止了银纳米微粒的团聚.     

原位还原法制备SBA-15介孔分子筛负载纳米银颗粒

利用一种温和的还原剂六亚甲基四胺(HMT)通过一步合成的方法制备了介孔Ag/SBA-15分子筛, 采用粉末X射线衍射(XRD)、透射电镜(TEM)和氮气吸附/脱附等手段对样品进行了表征. 样品的比表面积为525 m²/g, 平均孔径为5.4 nm. 用XPS、广角XRD和高分辨TEM等手段证实样品中的银为金属态的纳米颗粒. 研究结果表明, 以六亚甲基四胺为还原剂通过原位还原的方法能使银纳米颗粒较好地分散到介孔材料的孔道中.     

Two-Sided Antibacterial Cellulose Combining Probiotics and Silver Nanoparticles

The constant increase of antibiotic-resistant bacteria demands the design of novel antibiotic-free materials. The combination of antibacterials in a biocompatible biomaterial is a very promising strategy to treat infections caused by a broader spectrum of resistant pathogens. Here, we combined two antibacterials, silver nanoparticles (AgNPs) and living probiotics (Lactobacillus fermentum, Lf), using bacterial cellulose (BC) as scaffold. By controlling the loading of each antibacterial at opposite BC sides, we obtained a two-sided biomaterial (AgNP-BC-Lf) with a high density of alive and metabolically active probiotics on one surface and AgNPs on the opposite one, being probiotics well preserved from the killer effect of AgNPs. The resulting two-sided biomaterial was characterized by Field-Emission Scanning Electron Microscopy (FESEM) and Confocal Laser Scanning Microscopy (CLSM). The antibacterial capacity against Pseudomonas aeruginosa (PA), an opportunistic pathogen responsible for a broad range of skin infections, was also assessed by agar diffusion tests in pathogen-favorable media. Results showed an enhanced activity against PA when both antibacterials were combined into BC (AgNP-BC-Lf) with respect to BC containing only one of the antibacterials, BC-Lf or AgNP-BC. Therefore, AgNP-BC-Lf is an antibiotic-free biomaterial that can be useful for the therapy of topical bacterial infections.     

非水反相微乳中NaCl纳米粒子的制备

在乙醇/Brij 30/十六烷反相微乳中利用无水NaAc与HCl反应制备了水可溶性晶态NaCl纳米粒子,平均粒径为 60 nm.与在甲酰胺/AOT/正庚烷反相微乳中制备的粒径约为1 μm的NaCl粒子进行比较,表明在特定条件下,非水微乳可以作为合成水可溶性纳米粒子的有效介质.     

琥珀酸二异辛酯磺酸钠微乳体系中纳米银的制备及其连续相的影响

在琥珀酸二异辛酯磺酸钠(AOT)为表面活性剂、环己烷为连续相形成的微乳体系中, 利用水合肼还原AgNO₃制备了分散性良好的纳米银. 利用紫外-可见(UV-Vis)光谱和透射电镜(TEM)对所得产物进行了表征, TEM显微图像表明形成粒子为球形结构, 平均粒径为5.10 nm, 标准偏差为2.84 nm. 分别利用正己烷、正庚烷、正辛烷、环己烷和十二烷等作连续介质, 研究了微乳液中连续相对纳米银形成的影响. 随着正烷烃碳链长度的增加, 微乳液中胶束之间的交换速率增大, 形成粒子的平均粒径逐渐减小. 十二烷形成的微乳体系制备的纳米银溶胶具有最宽的共振吸收峰, 所得的纳米银粒子平均粒径最小. 环己烷形成的微乳液中反胶束具有特殊的界面强度, 导致纳米银晶核的形成速率过低, 纳米银晶粒的生长不完全.     

载Ag二氧化钛纳米管的制备及其光催化性能

Titania nanotubes (TNTs) were synthesized by hydrothermal treatment of rutile-phase TiO2 nanoparticles in 10 mol·L-1NaOHsolution at 110 ℃ for 24 h. The Ag loaded titania nanotubes (Ag/TNTs) were obtained by chemical deposition method with the TNTs suspending in the AgNO3 solution (pH=8) at 50 益. The characterizations of the as-synthesized samples were performed by TEM, EDS, XRD, XPS, and UV-Vis spectra. The photocatalytic performance of the Ag/TNTs was investigated by UV-light induced photocatalytic decomposition of methyl orange(MO). The results showed that the inner/outer diameters of TNTs were about 6/10 nm and the length was several hundred nanometers. Both the shape and the crystalline of the nanotubes were not changed after the modification. The zero oxidation state Ag quantumdots, about 4 nmin diameter, were well dispersed on the external surface of the nanotubes. Ag/TNTs exhibited enhanced absorption at the visible range in the UV-Vis spectra. The Ag nanoparticles were found to significantly enhance the photocatalytic activity of TiO2 nanotubes, and the catalyst system was demonstrated to be highly efficient for the UV-light induced photocatalytic decomposition of MO compared to both rutile-phase TiO2 nanoparticles and pure TNTs. After irradiation for 60 min, the decomposition rates of MO solution in rutile-phase TiO2 nanoparticles, TNTs, and Ag/TNTs systemwere 46.8%, 57.2%, and 92.2%, respectively.     

单分散纳米微粒制备方法研究进展

单分散纳米微粒既可以在严格控制的条件下直接制备，也可以通过对多分散纳米微粒体系进行分级分离获得。本文在总结近年来国内外单分散纳米微粒的研究工作的基础上，介绍了直接制备和分级分离这两种获得单分散纳米微粒的方法。     

Preparation of Ag Nanoparticles in Surfactant Solution

The physicochemical properties of Ag nanoparticles have been determined by the nature of the used chemical reductors. The reported procedures describe the reduction of silver ions using N‐Phenylbenzohydroxamic acid (PBHA) and ascorbic acid individually. The influencing factors including cationic, anionic, zwitterionic and nonionic surfactants and pH have also been investigated in detail.     

CdS纳米粒子的水热微乳法制备

0引言CdS是一种重要的Ⅱ-Ⅵ族半导体,其独特的光电化学性能引起人们的广泛关注,而其性能与晶粒尺寸、晶体结构等密切相关,因而CdS的纳米结构的研究备受关注[1￣3]。目前,制备CdS纳米粒子的主要方法有溶剂热法[4],化学浴沉积法[5],微乳液法[6]等。微乳液是合成球形纳米粒子的良好介质,具有实验装置简单,操作方便,应用领域广并且有可控制微粒的粒度等优点[7]。但其在室温条件下合成的CdS粒子的结晶性较差,严重影响其光电性能。Gan和Liu等[8]曾在NP5-NP9/PE/SOL微乳液中,在室温及水热条件下合成ZnS:Mn发光纳米材料,来提高在微乳液中制…