直接还原法制备超细铜银双金属粉及性能研究

超细铜粉、银粉由于其自身特性已被人们广泛应用于导电胶犤１，２犦、导电涂料、电极材料及抗菌材料犤３，４犦的制备等。但是铜粉、银粉都有一定的缺点，例如：超细铜粉很容易氧化，容易产生电迁移现象。超细银粉的成本又很高。如果将铜银结合起来制成铜银双金属粉，则在很大的程度上克服了铜粉的缺点犤５犦，又降低了银粉的成本。而双金属粉末还可以改变单一金属粉末的结构和性能，因此会表现出一些新的性能。如抗菌性，Cu－Ag粉既具有Cu的抗真菌性，又有Ag的抗细菌性等，具有广泛的应用前景。超细铜粉和超细银粉的制备已有许多相关的报…     

包覆型纳米铜-银双金属粉研究

目前,导电胶或者电磁波屏蔽涂料用的导电性填料主要有三类,一是铜粉,二是银粉,三是铜-银双金属粉。铜粉具有来源广、价格低廉、导电性好等优点,但其抗氧化性能弱;银粉导电性与抗氧化性好,但其资源日益匮乏。大量的研究试图通过对铜粉进行表面改性来提高其性能。表面改性有两种方法,一是包膜处理,用SiO2溶胶处理铜粉,铜粉抗氧化性能提高,但其表面导电性能大大降低犤1犦;另一类方法是在铜粉表面覆盖一层导电性能与抗氧化性能均佳的银或金而制成双金属粉末犤2～5犦。制取高性能的铜-银双金属粉是该领域的研究重点。目前获得铜-银双金属粉的方…     

新型磁性氧化石墨烯的制备及其载药性能

通过氧化超声剥离法制备出氧化石墨烯(GO),并通过原位化学共沉淀法将其与Fe_3O4复合,得到一系列组分质量比(m_(G/F))不同的磁性氧化石墨烯复合物(GO@Fe_3O_4).用X射线粉末衍射(XRD)、拉曼光谱(Raman)、傅里叶红外光谱(FTIR)、扫描电子显微镜(SEM)和振动样品磁强计(VSM)表征了复合物的组成、微观结构和形貌及磁性能.结果表明,复合物中Fe_3O_4纳米粒子包覆在GO的表面,且两组分之间存在一定的相互作用.进一步研究表明,复合物对抗癌药物—阿霉素(DOX)的吸附行为符合二级动力学模型;正交试验结果表明,温度、DOX浓度和溶液pH都会影响复合物的载药性能,其中DOX浓度的影响最大,而溶液p H最小.此外,复合物对DOX的释放性能受溶液p H的影响较大,当pH5.8时,复合物的累积释放率最高,且重复利用率较理想.     

超声分散对单壁碳纳米管分离的影响

利用凝胶柱色谱技术, 研究者们通过两步或多步淋洗的方法实现了不同导电属性或电子结构单壁碳纳米管(SWCNTs)的分离, 并提出其分离机制主要是由不同导电属性和电子结构的SWCNTs 与凝胶填料之间作用力的差异所导致的. 基于凝胶柱色谱分离技术, 本文重点考察了超声时间对单壁碳纳米管单分散以及金属型/半导体型SWCNTs 分离的影响. 在一定的低超声功率下, 适当增加超声时间有利于SWCNTs 在十二烷基硫酸钠(SDS)溶液中的单分散. 紫外-可见-近红外(UV-Vis-NIR)吸收光谱、拉曼(Raman)光谱和荧光(PL)光谱表征结果表明, 2 h的超声条件是获得高纯度的金属型以及不同直径分布的半导体型SWCNTs 的最优条件. 我们认为不同超声时间对SWCNTs 分离的影响主要是改变了SWCNTs 的单分散性和长度, 调制了不同SWCNTs 与凝胶之间作用力的差异, 从而导致了不同SWCNTs分离结果.     

可见光高催化活性GO/Ag3PO4/Ni复合薄膜的制备和性能

以磷酸铵和氧化石墨烯悬浊液的混合液为电解液,采用电化学共沉积法制备了Ag3PO4基GO/Ag3PO4/Ni复合薄膜。运用扫描电子显微镜(SEM)、能量色散谱(EDS)、X射线衍射(XRD)、拉曼光谱(Raman)和紫外可见漫反射光谱(UV-Vis DRS)等对其形貌、物相和光谱特性进行分析。最佳工艺制备的GO/Ag3PO4/Ni复合薄膜呈现出GO包覆在直径为100 nm左右的Ag3PO4纳米球外的表面形貌。GO片与Ag3PO4纳米球之间存在强电荷相互作用。与单独的Ag3PO4纳米球相比,GO片的附着导致带隙缩小,可见光区的吸收率增强。可见光下考察了复合薄膜降解罗丹明B的光催化活性和稳定性,并利用荧光光谱和捕获剂法对薄膜的光催化机理进行了探索。结果表明,GO片的加入不仅显著提高了Ag3PO4的光催化活性,而且提高了Ag3PO4的结构稳定性。光催化降解罗丹明B 60 min时,GO/Ag3PO4/Ni复合薄膜的降解率是Ag3PO4/Ni薄膜的1.32倍。在保持薄膜光催化活性基本不变的前提下可循环使用7次。GO优异的电荷传导性能,以及Ag3PO4纳米球与GO片之间的正协同效应是提高复合薄膜光催化性能的主要原因。     

微米级PS-PEDOT核壳型导电微球的合成与拉曼表征

以分散聚合法制备的微米级聚苯乙烯(PS)微球为模板、3,4-乙烯二氧噻吩(EDOT)为单体、过硫酸铵(APS)为引发剂,通过氧化聚合制备了PS-PEDOT核壳型复合导电微球。采用扫描电镜、透射电镜等对导电微球的形貌和结构进行了表征,重点采用拉曼光谱研究了其核壳结构特征。并研究了超声分散、溶液pH以及单体配比对导电微球形貌的影响。实验结果表明:超声的引入可提高导电微球的单分散性,改善微球的形貌。随着pH的降低或单体配比的增加,导电聚合物在PS微球表面的负载量随之增加,当m(EDOT)/m(PS)由0.60增加到1.25时,导电微球的平均粒径由1.76μm增加到1.91μm。     

耦合氧化石墨烯的N掺杂Bi_2O_2CO_3微球光催化性能增强机制(英文)

光催化作为一种环境友好技术,在解决环境污染和能源匮乏问题方面展现出巨大应用潜力.TiO_2因其化学稳定性、无毒和低成本被广泛应用于能源转换和污染物降解等领域,但其快速的电子-空穴复合与低太阳能利用率等限制了其在光催化中的潜在应用.因此,寻找新的有优越可见光活性的催化剂是一个挑战.最近,(BiO)_2CO_3因其独特的形貌、化学稳定性和较高的催化效率成为有前景的光催化剂.然而,(BiO)_2CO_3较大的带隙限制了对太阳光的利用,快速的电子-空穴复合阻碍了光催化性能的提高.因此,提高(BiO)_2CO_3的光催化效率是当务之急.近期研究表明,通过与氧化石墨烯杂交提高载流子的分离能力,可有效增强光催化性能.基于此,我们设计并合成了一种氮掺杂的(BiO)_2CO_3与氧化石墨烯(GO)耦合的新型光催化剂(N-BOC-GO).首先,通过一步水热法合成了N-BOC-GO微球.N-BOC-GO光催化剂对NO可见光光催化去除性能达到62%.采用X射线衍射(XRD)、X射线光电子能谱(XPS)、扫描电子显微镜(SEM)、紫外-可见漫反射光谱(UV-Vis)和光致发光光谱(PL)等表征手段研究了N-BOC-GO的光催化性能增强机制.从N-BOC-GO的XRD谱中没有发现GO的衍射峰,说明加入的GO分散度高;N-BOC-GO中的BOC晶格参数没有发生变化,说明GO没有进入BOC晶格,但加入GO增强了N-BOC的结晶度.XPS结果表明,与N-BOC相比,N-BOC-GO的峰位置发生了明显位移,表明N-BOC和GO之间存在强相互作用.此外,FT-IR和拉曼光谱证明了在复合物中存在GO.SEM表明,N-BOC规则地团聚成微球,且微球被固定在有褶皱的GO片上.这说明GO与N-BOC的作用是静电作用或物理作用,在光激发过程中有利于N-BOC微球上的电子转移到GO片上.UV-Vis图谱中,N-BOC-GO表现出明显增强的可见光吸收,说明加入GO会明显提高N-BOC的吸收能力.此外,3D分层结构会通过SSR效应提高光吸收.从PL图可以发现,N-BOC-GO的电子-空穴复合明显下降,说明GO可以转移电子从而提高光催化性能.结合前面的分析,我们提出了N-BOC-GO光催化剂3D分层结构的形成和性能增强机制.在水热过程中,通过分子间相互作用使N-BOC自组装成块,随后在表面能最小化的作用下转化成3D微球.加入GO后,N-BOC和GO通过物理吸附使得N-BOC微球均匀分散在GO上,最后N-BOC-GO的形貌类似于玫瑰花和其叶子的组合.在可见光照射下,N-BOC产生电子-空穴对,电子从N-BOC表面转移到GO表面,表明GO可作为电子的收集者和传递者以有效分离电子-空穴对,延长载流子寿命.N-BOC价带上的空穴可以直接氧化NO或产生?OH氧化NO.此外,由于GO独特的特征,光催化反应发生在N-BOC催化剂表面和GO片上,从而提高了反应空间位点.故引入GO于N-BOC体系中可有效分离光生载流子和提高反应活性位点,从而显著提高可见光催化性能.     

聚苯胺表面修饰芳纶浆粕及其纸基材料的导电性能

通过在芳纶浆粕(AP)表面修饰聚苯胺(PANI)制备了聚苯胺-芳纶浆粕(PANI-AP), 然后与碳纤维(CF)共混, 采用湿法抄纸技术制备导电性能优异的纸基材料(PANI-AP/CP). 对其形貌结构、 导电性能及PANI分布均匀性进行了表征, 并研究了环境湿度、 温度、 pH值及放置时间对PANI-AP/CP导电性能的影响. 研究结果表明, PANI-AP表面粗糙度增加, 结晶度增加, 出现含醌式结构的导电PANI的衍射峰, 说明PANI成功修饰于AP表面. 采用该方法制备的PANI-AP/CP导电性能与分布均匀性均得到提高, 相对于碳纤维纸基材(CP), PANI-AP/CP的电导率为3.937 S/cm, 导电性能提高153.5%. 与PANI原位生长于CP(AP/CP-PANI)相比, PANI-AP/CP的导电性能提高34.6%, 总色差值(DE)降低74.9%.     

Fe_3O_4/PEI/GO复合材料的制备及其吸附效果研究

以氧化石墨烯(GO)和聚乙烯亚胺(PEI)为反应物,采用共混法制备PEI/GO,然后将Fe_3O_4纳米颗粒分散沉积到PEI/GO表面,得到了复合材料Fe_3O_4/PEI/GO。利用傅里叶红外光谱(FT-IR)、透射电子显微镜(TEM)、X射线衍射(XRD)和X射线光电子能谱(XPS)等方法对该材料进行表征,并研究了其对Cu~(2+)的吸附性能。结果表明,PEI与GO的羧基反应生成了酰胺键,Fe_3O_4成功沉积在GO表面,GO层状结构的规整性被破坏。Freundlich等温吸附模型和准二级动力学模型能更好地拟合Cu~(2+)在Fe_3O_4/PEI/GO表面的吸附过程,说明该吸附主要受化学作用控制,可能是Fe_3O_4/PEI/GO表面的胺基、羧基、羟基等活性基团与Cu~(2+)发生了离子交换或络合反应所致。     

阳极氧化膜In2O3（Ⅰ）—膜的形成和电子性质

利用循环伏安法和X射线光电子能谱技术(XPS)研究In在碱性溶液中的电极反应,结果表明通过阳极氧化可在In电极表面形成In_2O_3膜.探讨能获得较高光电转换量子效率的In_2O_3膜的电化学制备方法,并利用Mott-Schottky图、光电流谱和电反射光谱的测量测定膜的半导电性质.     

Free‐standing Graphene/Poly(methylene blue)/AgNPs Composite Paper for Electrochemical Sensing of NADH

Highly flexible graphene/poly(methylene blue)/AgNPs composite paper was successfully prepared for amperometric biosensing of NADH. For this purpose, a dispersion including graphene oxide (GO), methylene blue (MB) and silver nanoparticles (AgNPs) was prepared and GO/MB/AgNPs paper was acquired by vacuum‐filtration of this dispersion through a suitable membrane. After peeling it off from membrane, it was transformed to rGO/MB/AgNPs paper by performing reduction with hydriodic acid. In a three‐electrode cell, which is containing 0.1 M phosphate buffer solution (pH: 9.0), rGO/MB/AgNPs paper was used as working electrode and rGO/poly(MB)/AgNPs composite paper was generated by surface‐confined electropolymerization of MB using successive cyclic voltammetry approach in a suitable potential window. Characterization of this composite paper was carried out by using scanning electron microscopy, scanning tunneling microscopy, X‐ray photoelectron spectroscopy, powder X‐ray diffraction spectroscopy, Raman spectroscopy, four‐point probe conductivity measurement and cyclic voltammetry techniques. Flexible rGO/poly(MB)/AgNPs composite paper has demonstrated high sensitivity, wide linear range and low detection limit for amperometric quantification of NADH.     

Epoxy‐based composite adhesives: Effect of hybrid fillers on thermal conductivity,rheology, and lap shear strength

Thermal management is an important parameter in an electronic packaging application. In this work, three different types of fillers such as natural graphite powder (Gr) of 50‐μm particle size, boron nitride powder (h‐BN) of 1‐μm size, and silver flakes (Ag) of 10‐μm particle size were used for thermal conductivity enhancement of neat epoxy resin. The thermal properties, rheology, and lap shear strength of the neat epoxy and its composite were investigated. The analysis showed that the loading of different wt% of Gr‐based fillers can effectively increase the thermal conductivity of the epoxy resin. It has also been observed that the thermal conductivity of the hybrid filler (Gr/h‐BN/Ag) reinforced epoxy adhesive composite increased six times greater than that of neat epoxy resin composite. Further, the viscosity of hybrid filler reinforced epoxy resin was found to be increased as compared with its virgin counterpart. The adhesive composite with optimized filler content was then subsequently subjected to determine single lap shear strength. The degree of filler dispersion and alignment in the matrix were determined by scanning electron microscopy (SEM) analysis.     

银纳米晶体的制备与表征

在聚乙烯吡咯烷酮存在的条件下,用水合肼还原硝酸银,通过控制反应条件成功制备出了粒径均一、有良好分散性的银纳米微粒,并以此为种子,利用种子诱导生长,在十六烷基三甲基溴化铵的棒状胶束环境中制备出了银纳米棒和纳米线.并用X射线衍射、透射电子显微镜、傅立叶红外光谱和紫外-可见光谱等手段对产品的形貌、结构进行了表征.     

Preparation of Ultrafine Pigment Dispersion and Effect on ξ‐Potentials

The waterborne ultrafine pigment C.I.P.B15∶1 dispersion was prepared with copolymer by the phase separation method. The shape and size distribution of ultrafine pigment particles were investigated, and the effects of pH value, ion intensity, and alcohols on ξ‐potentials were analyzed. The results showed that stick‐shaped particles with narrow distribution were obtained, ξ‐potentials obviously increased with increasing of pH value in the range of 5–9, and when the pH value was at 8–9, the ξ‐potential reached its maximum. Moreover ξ‐potentials decreased with increasing ion intensity, decreased by adding the alcohols into the dispersion, and also decreased with increase in the dosage of Triton TX‐10.     

Green Synthesis of Ag Nanoparticles by Callicarpa Maingayi: Characterization and Its Application with Graphene Oxide for Enzymeless Hydrogen Peroxide Detection

A facile green synthesis of silver nanoparticles (AgNPs) was achieved using aqueous leaf extract of Callicarpa Maingayi as a reducing and stabilizing agent during the synthesis from its salt solutions. The synthesized silver nanoparticles were analyzed with transmission electron microscopy (TEM), X‐ray diffraction (XRD) and energy dispersive spectrometer (EDS). XRD study shows that the particles are crystalline in nature with face centered cubic geometry. The crystallite size obtained from XRD is about 15 nm which is in agreement well with the TEM results. A new nanostructure sensor was constructed by immobilizing silver nanoparticles and graphene oxide (AgNPs‐GO) composite film on a glassy carbon electrode (AgNPs‐GO/GCE). It was found that the AgNPs‐GO composite exhibits good catalytic activity toward the reduction of hydrogen peroxide (H₂O₂), leading to an enzymeless sensor with a fast amperometric response time of less than 5 s, high selectivity, good reproducibility and stability. The linear range was 5.0 μM to 700 μM with a detection limit of 0.6 μM (S/N = 3).     

LaFeO~3超微粒子的制备及性质的研究

本文使用溶胶-凝胶法制备了平均粒径为12~75nm的LaFeO~3超微粒子。从凝胶至超微粒子的过程中, 失重达90%。纯相晶态的LaFeO~3超微粒子的最低生成温度为600℃。粒子平均粒径随着灼烧温度的升高而显著增大, 通过对不同粒径的LaFeO~3超微粒子表面光电压光谱的研究发现, 随着粒子粒径的增大, 粒子内部逐渐形成长程有序的晶体结构和完整的能带结构。粒子粒径越小, 表面特性越明显。     

Preparation and Characterization of a Composite of Silver Iodide and Synthetic Mordenite

A composite material made up of AgI and the potassium form of mordenite has been prepared by treating the silver form of synthetic mordenite with potassium iodide. The composite as well as the silver and potassium forms of mordenite have been characterised by X-ray powder diffractometry, X-ray photoelectron spectroscopy, EDS analyses and ac conductivity measurements. It has been inferred that, in the composite material, AgI grows at the entrance of the zeolite channels without forming a continuous conducting phase. The silver form of mordenite has been proved to be a silver ion conductor by dc conductivity measurements.     

Ultrafine agarose-coated superparamagnetic iron oxide nanoparticles (AC-SPIONs): a promising sorbent for drug delivery applications

A method for one-step synthesis of ultrafine agarose-coated superparamagnetic iron oxide nanoparticles (AC-SPIONs) was developed. The method is facile and fast and requires no organic solvent or surfactant. The average particle size of the prepared AC-SPIONs was only 20–40 nm with a narrow size distribution and with large saturation magnetization at room temperature. The obtained ultrafine nanogel particles were characterized by scanning electron microscopy, energy-dispersive X-ray analysis, Fourier transform infrared spectroscopy, transmission electron microscopy and vibrating sample magnetometer techniques. The AC-SPIONs were epoxy-activated by epichlorohydrin and aminated by ammonium hydroxide. The amination of the particles was investigated by the Kaiser test. The adsorption of two model compounds (gallic acid and ellagic acid) on the functionalized nanoparticles and their releases from them were investigated spectrophotometrically in three different pH values under biological conditions. The functionalized AC-SPIONs displayed good adsorption and in vitro drug release in a phosphate-buffered saline (pH 7.4). The ultrafine AC-SPIONs can be potentially used in magnetic solid-phase extraction, drug delivery, protein purification and enzyme immobilization methods.     

Synthesis of tin and tin oxide nanoparticles of low size dispersity for application in gas sensing

Nanocomposite core-shell particles that consist of a Sn0 core surrounded by a thin layer of tin oxides have been prepared by thermolysis of [(Sn(NMe2)2)2] in anisole that contains small, controlled amounts of water. The particles were characterized by means of electronic microscopies (TEM, HRTEM, SEM), X-ray diffraction (XRD) studies, photoelectron spectroscopy (XPS), and Mossbauer spectroscopy. The TEM micrographs show spherical nanoparticles, the size and size distribution of which depends on the initial experimental conditions of temperature, time, water concentration, and tin precursor concentration. Nanoparticles of 19 nm median size and displaying a narrow size distribution have been obtained with excellent yield in the optimized conditions. HRTEM, XPS, XRD and Mossbauer studies indicate the composite nature of the particles that consist of a well-crystallized tin beta core of approximately equals 11 nm covered with a layer of approximately equals 4 nm of amorphous tin dioxide and which also contain quadratic tin monoxide crystallites. The thermal oxidation of this nanocomposite yields well-crystallized nanoparticles of SnO2* without coalescence or size change. XRD patterns show that the powder consists of a mixture of two phases: the tetragonal cassiterite phase, which is the most abundant, and an orthorhombic phase. In agreement with the small SnO2 particle size, the relative intensity of the adsorbed dioxygen peak observed on the XPS spectrum is remarkable, when compared with that observed in the case of larger SnO2 particles. This is consistent with electrical conductivity measurements, which demonstrate that this material is highly sensitive to the presence of a reducing gas such as carbon monoxide.     

Environmentally sensitive silver nanoparticles of controlled size synthesized with PNIPAM as a nucleating and capping agent

Metal nanoparticles combined with environmentally sensitive polymers can lead to enhanced nanometer-sized switches. We present a silver nanoparticle synthesis method that uses poly(N-isopropylacrylamide) (PNIPAM) as the nucleating, capping, and stabilizing agent. The synthesis is performed at room temperature by sodium borohydride-mediated reduction of silver nitrate in the presence of a fully hydrated polymer. The resulting metal nanoparticles have a narrow size distribution comparable to or better than those achieved with other synthesis methods. The silver particles can be thermally precipitated by the collapse of the PNIPAM shell and resolubilized with fast response times, as shown by surface plasmon spectroscopy. The silver-PNIPAM composite allows for combined surface plasmon and thermal switching applications.