Q-CdS/聚合物纳米复合膜的制备与荧光性能

采用配位化学合成原理 ,分离制备出颗粒尺寸小于 10nm的单分散性的Q态CdS(Q CdS)纳米粒子 ,将Q CdS纳米粒子与聚合物复合成膜 ,制备出一系列Q CdS 聚合物纳米复合膜 .用紫外可见吸收光谱与透射电镜研究了纳米复合膜的量子尺寸效应和分散性 .通过荧光光谱探讨了不同聚合物基体材料和不同Q CdS含量的纳米复合膜的荧光发光性能 .结果表明 ,一方面这种以聚合物为基体的纳米复合膜 ,由于聚合物与Q CdS之间的相互作用 ,使纳米复合膜表现出与单一相组分完全不同的特征荧光发射峰 ;另一方面 ,随着纳米复合膜中Q CdS含量的不断增大 ,纳米复合膜的荧光强度不断增强 ,在一定浓度时达到最大值 .     

巯萘剂表面修饰的CdS纳米微粒的合成及发光特性

用疏萘剂(TN)作为表面修饰剂,在甲醇溶液中合成了CdS/TN纳米微粒,用TEM测得纳米微粒呈球形,其粒径约10nm,吸收光谱和荧光光谱研究表明,[S^2-]/[TN]浓度比、TN和镉离子的浓度对CdS/TN纳米微粒的粒径及发光特性具有显著影响,且随着条件的改变,CdS/TN纳米微粒的发射波长红移100nm,表现出明显的量子尺寸特性.XPS显示所制得表面修饰纳米微粒的核为CdS.     

单分散CdS纳米晶/PNIPAM复合水凝胶的制备及其温敏荧光特性

采用液体-固体-溶液法(LSS)制备单分散CdS纳米晶;通过自由基聚合制备单分散CdS纳米晶/聚N-异丙基丙烯酰胺(CdS/PNIPAM)复合温敏水凝胶.采用HRTEM、XRD、FTIR、DSC、PL等对CdS纳米晶、CdS/PNIPAM温敏复合凝胶的微观结构与性能进行了表征,变温荧光光谱研究了温度对凝胶荧光性能的影响.结果表明,CdS纳米晶粒径约为2.8 nm,单分散性良好;复合凝胶的荧光发射强度与环境温度存在一定的关联性,且呈可逆性.     

表面修饰CdS和(CdS)ZnS纳米晶的性能研究

在水相中合成了CdS纳米微粒,以ZnS对其进行表面修饰,得到具有核壳结构的(CdS)ZnS水溶性纳米晶。采用红外光谱、X射线衍射(XRD)、透射电镜(TEM)表征其粒度和形貌,紫外-可见吸收光谱(UV)、荧光光谱表征其光学特性。制得的CdS近似呈球形,直径为8nm;CdS纳米颗粒表面经ZnS修饰后,其荧光发射峰强度显著增强,表面态发射减弱。     

CdS/TiO2复合纳米粒子的光学性质

在Brij35/正己醇/环己烷/水构成的反相微乳体系中，分别合成了CdS、TiO2纳米粒子和TiO2包覆CdS（CdS/TiO2）的复合纳米粒子.测定了它们的紫外-可见吸收和荧光光谱.结果表明， CdS/TiO2复合纳米粒子在可见光区的吸收比相应的两组分的吸收之和更强.纳米CdS和纳米TiO2均有较强的荧光.而且在相同浓度时纳米TiO2的荧光比纳米CdS的荧光更强.但在CdS/TiO2复合纳米粒子中，TiO2的荧光被淬灭，而CdS的荧光稍有降低.     

纳米CdS/聚乙烯咔唑(PVK)复合材料制备与表征

采用反相微乳法在庚烷/琥珀酸二异辛酯磺酸钠(AOT)/水体系中成功制备出纳米CdS/聚乙烯咔唑(PVK)复合材料。通过紫外-可见光谱(UV-Vis)、X射线衍射(XRD)、透射电子显微镜(TEM)、荧光光谱(PL)对复合材料进行了结构表征和形貌观察。结果表明,UV-Vis光谱吸收峰在325 nm和360 nm,表现出纳米粒子明显的量子尺寸效应;TEM照片显示纳米CdS粒径分布较窄,均匀分散在PVK中。XRD分析表明,CdS纳米颗粒已经形成。PL结果显示:产物的荧光发射光谱峰波长在375 nm和520 nm。     

溶胶-凝胶法制备Tb-PDA/PVA薄膜及其荧光性能

采用溶胶-凝胶法制备了铽(Ⅲ)-吡啶-2,6-二羧酸/聚乙烯醇(Tb-PDA/PVA)发光薄膜,其结构经IR,差热分析,原子力显微镜及荧光光谱表征.分析结果表明:薄膜表面平整,PVA中的纳米Tb-PDA(平均粒径为90 nm)分散均匀,在270 ℃以下具有良好的热稳定性.在紫外光照射下,薄膜发出较强的绿色荧光,最大发射峰位于544 nm,归属于Tb3+的5D4→7F5跃迁.     

水热合成CdS纳米晶体的形貌控制研究

研究了水热合成CdS纳米晶体形貌的化学控制，选择不同的络合试剂为模板,研究其对水热合成CdS纳米晶体形貌的影响.实验发现若以络合试剂乙二胺、甲胺为模板时，产品CdS晶体的形貌分别为（20～30） nm×（200～600） nm和（40～50） nm×（200～600） nm尺寸的纳米棒;而以络合试剂吡啶、 氨为模板时，产品CdS晶体的形貌分别为平均尺寸约30 nm和20 nm的纳米颗粒.用XRD、TEM、XPS、PL和Raman光谱等技术对所得CdS纳米棒进行了表征.同时对水热合成CdS纳米晶体形貌的模板控制机制进行了探讨，提出了一种水热合成CdS纳米棒的络合物结构诱导生长机理.     

Cu2+掺杂CdS纳米晶的制备与表征

以巯基乙酸为稳定剂,采用水相合成法制备了Cu2+掺杂的CdS纳米晶. 分别用电感耦合等离子体发射光谱仪、原子力显微镜测试技术对样品的化学成分及形状进行分析表征,研究了掺杂CdS纳米晶的荧光激发与发射光谱. 实验结果表明,在样品制备过程的溶液中回流2 h后,组成为Cd0.99Cu0.01S的样品形状有棒状和粒状2种,Cu2+的掺入使得CdS纳米晶的荧光发射光谱红移,没有掺杂的样品在回流前的最大发射波长在520 nm处,而组成为Cd0.99Cu0.01S和Cd0.98Cu0.02S的样品在回流前的最大发射波长分别为595和610 nm,通过改变Cu与Cd摩尔比可调控CdS纳米晶的发射波长范围.     

聚苯胺对纳米CdS的光致发光增强效应

利用电化学脉冲沉积法在聚苯胺(PANI)膜上制备了纳米CdS/PANI复合膜,并利用扫描电镜光谱、紫外可见光谱、红外光谱、拉曼和荧光等光谱技术表征复合膜的形貌、结构及性质.CdS/PANI复合膜中CdS微粒呈现量子尺寸效应;CdS和PANI间存在相互作用;由于聚苯胺和CdS能级的合适匹配,聚苯胺对CdS的光致发光(PL)有增强效应,增强机理为光生载流子的传递机理.     

纳米铝/金对纳米二,五-二苯基噁唑薄膜荧光特性的调制

以直流溅射方法和真空蒸镀方法结合制备了单组份纳米铝薄膜、纳米金薄膜、纳米二,五-二苯基噁唑(DPO)薄膜和双组份纳米Al/DPO、Au/DPO复合叠层薄膜。利用双势垒伏安特性曲线模拟计算、荧光分光光度计和扫描电子显微镜(SEM)表征了薄膜样品的电学性质、荧光性质和表面形貌。固态荧光光谱观察到500nm膜厚的Au/DPO、Al/DPO叠层结构复合纳米薄膜样品的荧光主峰发生了明显红移。Au/DPO叠层结构复合薄膜样品与单组份DPO纳米薄膜样品的荧光发射光谱相比较,叠层薄膜内相互作用较弱,而Al/DPO叠层结构复合纳米薄膜样品相互作用较强、谱线峰型变化较大,Al的谱线的半高全宽明显增大,推测颗粒内部存在离散的能级结构。     

Semiconductor nanoparticle/polystyrene latex composite materials

Cadmium sulfide and cadmium selenide/cadmium sulfide core/shell nanoparticles stabilized with poly(cysteine acrylamide) have been bound to polystyrene (PS) latexes by three methods. First, anionic 5 nm diameter CdS particles were electrostatically attached to 130 nm surfactant-free cationic PS latexes to form stable dispersions when the amount of CdS particles was less than 10% of the amount required to form a monolayer on the surface of the PS particles or when the amount of CdS particles exceeded the amount required to form a monolayer on the PS particles. Transmission electron microscopy (TEM) showed nanoparticles on the surface of the latex particles. Fluorescence spectra showed unchanged emission from the nanoparticles. Second, anionic, surfactant-free PS latexes were synthesized in the presence of CdS and CdSe/CdS nanoparticles. TEM showed monodisperse latex particles with trapped nanoparticles. Third, surfactant-stabilized latexes were synthesized by copolymerization of styrene with vinylbenzyl(trimethyl)ammonium chloride electrostatically bound to the CdSe/CdS nanoparticle surface. Brownian motion of the submicroscopic composite particles in water was detected by fluorescence microscopy.     

ITO/TiO2表面电沉积CdS纳米粒子及其薄膜的光电性能

采用阴极恒电位沉积方法, 在TiO2表面沉积制备出CdS纳米粒子. XRD和SEM测试结果表明, CdS粒子的结构以六方晶相为主, 粒径分布均匀, 表面形貌呈菜花状. 通过调节沉积电位和沉积时间等因素在一定程度上可以控制CdS纳米粒子的生长. 随着沉积电位变负, CdS粒子的粒径逐渐减小. 沉积时间越短, 粒子粒径越小. 紫外-可见吸收光谱测试结果表明, 不同条件下制备出来的CdS粒子表现出一定的量子尺寸效应. 此外, 沉积条件也会影响ITO/TiO2/CdS复合半导体薄膜的光电性能.     

Effect of nano cadmium sulfide on combustion and thermal decomposition of polystryene and poly(methyl methacrylate)

Cadmium sulfide nano particles, both hollow spheres (CdS‐HS) and rods (CdS‐NR), were synthesized by ultrasonic and solvothermal processes, respectively, and characterized by XRD and SEM. The effect of the two kinds of nano particles on flammability was investigated using the cone calorimeter and microscale combustion calorimeter. The incorporation of small amount of CdS nano particles (1 wt.%, 3 wt.%, 5 wt.%) leads to a reduction in the peak heat release rate (PHRR) compared to pristine PS; CdS‐NR is more efficient in reducing the PHRR. CdS nano particles are less effective in reducing the PHRR of PMMA. Thermal stability of PS/CdS and PMMA/CdS nanocomposites was studied by TGA. The TGA results show that the addition of the nano particles mainly increases thermal stability of PS and PMMA at high temperatures. Copyright © 2014 John Wiley & Sons, Ltd.     

A new solid-phase nanoparticle FRET assays based on GO/CS/ZnS nanocomposite film and developed in sensing for bromonium ion

Composite thin films consisting of nano-sized ZnS particles dispersed in chitosan/GO films have been prepared by in-situ method. The films obtained were characterized by FTIR and UV–Vis spectroscopy. The ZnS nanoparticles with 90 nm in diameter were dispersed uniformly in the film matrix. Optical absorption peak due to the size of ZnS particles was observed around 350 nm. The fluorescence emission at 430 nm of the GO/CS/ZnS nanocomposite films is very sensitive to the presence of bromonium ion from aqueous solutions. New solid-phase nanoparticles FRET assays are firstly immobilized on the substrate and then interacted with functionalized acceptor molecules in the solution to trigger the FRET effect to detect Br^–.     

单分散性银纳米粒子的可控制备

以卤化银或氧化银作为前驱体,室温下以水为溶剂,在较高溶液浓度下,利用化学还原法制备了单分散性银纳米粒子,并通过改变前驱体的种类,实现了粒径可控制备。采取扫描电子显微镜（SEM）、紫外-可见光谱仪（UV-Vis）、X射线-粉末衍射仪（XRD）、X射线-光电子能谱仪（XPS）等对所制备的银纳米粒子的形貌及成分进行了表征。结果显示,所制备的银纳米粒子具有较高的单分散性,粒径在40~150 nm之间,具有面心立方多晶结构。该方法制备的银纳米粒子可用于喷墨打印RFID天线。     

Porous phosphate heterostructures containing CdS quantum dots: assembly, characterization and photoluminescence

The synthesis and characterization of cadmium sulphide (CdS) quantum dots, conjugated in a porous phosphate heterostructure functionalized with aminopropyl groups is described. The resulting material has fluorescence properties with maximum emission intensity at 575 nm. The fluorescent materials are not soluble in water and exhibit high stability in aqueous solution in the pH ranges from 2 to 9. Energy dispersive X-ray spectroscopy confirmed the qualitative elemental composition of the synthesized materials and X-ray photoelectron spectra showed a surface S/Cd atomic ratio of 1.09. SEM images show that the materials are amorphous, possessing porous with sizes of several tens nanometres, homogeneous and exhibit a layered morphology. The adsorption–desorption analysis by N₂ at 77 K showed the accessibility of the CdS quantum dots onto the pores of the structure. The CdS quantum dots were stabilized by mercaptopropionic acid and bounded to the host materials by amine groups.     

The green synthetic approach to prepare PbS/chitosan nanocomposites and its new optical sensing active properties for 2-isonaphthol

PbS nanoparticles were successfully synthesized in the presence of chitosan (CS) through an in situ method. This method is an effective, simple, and green synthetic approach to preparing nanomaterial films. The structure, morphology, and stability of the materials were examined via Fourier transform infrared spectroscopy, and the characteristic peak of the NH₂ group shifted from 1554 to 1598 cm^-1 after PbS was formed in the film. The Pb–S bond exhibited a vibrational absorption peak at 605 cm^-1, which further confirmed the generation of PbS nanoparticles. Differential scanning calorimetry (DSC) and scanning electron microscopy (SEM) procedures were performed as well; well-defined nanoparticles were detected in the CS matrix by SEM. As per DSC findings, the thermal stabilities of the PbS/CS film were 50°C higher than those of pure CS. Moreover, the fluorescence emission of the films was sensitive to the presence of 2-isonaphthol. The effect of 2-isonaphthol concentration on the emission of films increases significantly with an increase in this concentration. The concentration-dependent fluorescence can be described by a correlation equation when 2-isonaphthol concentration ranges from 0 to 12.56 mg/L, and fluorescence results revealed that the PbS/CS nanoparticles were sensitive to 2-isonaphthol in the liquid phase. The proposed method may be applied to detect 2-isonaphthol in the environment and in the chemical industry.     

Cds纳米微粒的聚四氟乙烯多孔膜法制备及其表面修饰

硫化镉;Cds纳米微粒的聚四氟乙烯多孔膜法制备及其表面修饰;纳米粒;多孔膜;表面修饰;聚四氟乙烯     

Preparation and optical properties of blue-emitting colloidal CdS nanocrystallines by the solvothermal process using poly (ethylene oxide) as the stabilizer

Blue-emitting colloidal CdS nanocrystals have been synthesized through the solvothermal reaction of cadmium acetate and thiourea in N,N-dimethylformamide using poly(ethylene oxide; PEO) as the stabilizing polymer. The as-prepared CdS colloids were stable at ambient conditions for several weeks. The PEO-stabilized CdS colloids showed a narrow fluorescence band with the maximum at about 420 nm and thus emitting blue fluorescence under the ultraviolet (UV) lamp. A common red shift of fluorescence band is not detected for the prepared CdS colloids in the study, indicating that PEO-stabilized CdS NCs possess few crystalline defects on their surface. In addition, transmission electron microscope micrographs reveal that the sizes of CdS NCs are between 4.4 to 5.4 nm with small standard deviations from 0.5 to 0.7 nm. The particle growth kinetics was studied by monitoring UV-visible absorption onsets versus the reaction time and was found to nearly follow the Lifshitz–Slyozov–Wagner theory for the Ostwald ripening mechanism.