聚苯胺/金属纳米粒子复合物的制备及性能

基于国内外最新研究文献及本课题组研究工作,从发展历史、制备方法、多功能性方面系统综述了近年来发展起来的聚苯胺/金属纳米粒子复合物。在聚苯胺基体中引入金属纳米粒子的方法可归纳为3大类：原位复合法、直接共混法和层层自组装法。所形成的有机聚苯胺和无机金属杂化复合物不仅能保留各自原有的特异性能,而且二组分之间还存在着相互协同作用,能够极大地提升基体聚苯胺材料的性能,电导率最高可提高100倍,电氧化催化电流最高可提高10倍。分散在聚苯胺膜中的极少量铂微粒就能使不锈钢板的腐蚀电位稳定在钝化区域。聚苯胺/金属纳米粒子复合物所表现出的突出的固有电导性、优异的反应催化性和极强的金属防腐性,使其跻身于为数不多的新型高性能复合材料之列,显示出了诱人的应用前景。     

贵金属多孔纳米结构的模板法制备及生物检测应用

贵金属多孔纳米材料是一类非常重要的新型多功能纳米材料,其具有独特的空心内部、多孔的外壁以及可调的形貌等,表现出优异的光、电、催化等特性。调制贵金属多孔纳米材料的尺寸、形状、排列和空间取向等对促进其在拉曼光谱、生物传感等方面的应用至关重要。模板法是利用与目标产物的纳米尺度特征相匹配的预制结构来指导纳米材料的合成,可以制备出其他方法难以制备的新型多孔纳米结构材料。基于模板的多样性,能够便捷的调节多孔贵金属的孔径、尺寸和组分,充分的开发贵金属纳米结构的特性。本文着重介绍了贵金属多孔纳米材料的类型和调控这些纳米结构的各种模板方法,分析了各种制备方法的优势和不足,并简要综述了贵金属多孔纳米结构在生物检测方面的一些应用进展。     

Electrodynamics of Noble Metal Nanoparticles and Nanoparticle Clusters

In this paper we examine the electrodynamics of silver nanoparticles and of clusters of nanoparticles, with an emphasis on extinction spectra and of electric fields near the particle surfaces that are important in determining surface-enhanced Raman (SER) intensities. The particles and clusters are chosen to be representative of what has been studied in recent work on colloids and with lithographically prepared particles. These include spheres, spheroids, truncated tetrahedrons, and clusters of two or three of these particles, with sizes that are too large to be described with simple electrostatic approximations but small compared to the wavelength of light. The electrodynamics calculations are mostly based on the discrete dipole approximation (DDA), which is a coupled-finite element approach which produces exact or nearly exact results for particles of arbitrary size and shape if fully converged. Mie theory results are used to study the validity of the DDA for spherical particles, and we also study the validity of the modified long wavelength approximation (MLWA), which is based on perturbative corrections to the electrostatic limit, and of the single dipole per particle approximation (SDA). The results show how the dipole plasmon resonance properties and the electric field contours around the particle vary with particle shape and size for isolated particles. For clusters of particles, we study the effect of interparticle spacing on plasmon resonance characteristics. We also show that the quadrupole resonance is much less sensitive to particle shape and interparticle interactions than the dipole plasmon resonance. These results provide benchmarks that will be used in future comparisons with experiment.     

贵金属复合纳米粒子的研究进展

贵金属复合纳米粒子具有不同于单组分纳米粒子的独特的光、电和催化等物理与化学性能,是构筑新型功能复合材料的重要单元,在传感器、光学材料、催化剂及生物领域都有着重要应用,已成为当前纳米材料科学研究领域中的前沿和热点。本文主要评述了具有核壳、异质结构以及合金结构的贵金属复合纳米粒子的制备、物理与化学性能及应用等方面的研究进展。     

贵金属纳米颗粒的微生物合成

金属纳米颗粒在材料、催化、医学、环境等众多领域应用广泛,其中,金、银、铂、钯等贵金属的纳米颗粒作为良好的催化剂可提高反应的速率,因此,贵金属纳米颗粒的合成吸引了众多研究者的关注。传统的物理化学法虽能高效、可控地合成贵金属纳米颗粒,但是合成条件苛刻、成本昂贵、且会产生对环境有害的化学物质。因此,探索节能、环保、可持续的绿色合成方法成为纳米合成研究的热点之一。贵金属纳米颗粒的微生物合成法具备绿色合成技术的诸多要素,研究表明某些微生物能将金属盐转化成纳米材料,且微生物繁殖速度快、培养成本低、生长条件温和,从而得到了研究者们的广泛关注。本文归纳总结了目前微生物合成贵金属纳米颗粒的主要研究进展,包括贵金属纳米颗粒可能的合成机制以及尺寸与形貌控制方法,探讨了其在医学、催化、生物传感、环境方面的具体应用,并对贵金属纳米颗粒微生物合成的未来发展进行了展望。     

生物法制备各向异性贵金属纳米粒子的研究进展

利用生物法绿色合成各向异性的贵金属纳米粒子(Au,Ag)具有经济环保、制备简单、无毒副作用等优点,成为近年来的研究热点。 本文通过介绍各向异性贵金属纳米粒子的物理化学性质,归纳了生物法,尤其是利用植物源生物质制备各向异性贵金属纳米粒子的研究,并在此基础上进一步阐述了各向异性贵金属纳米粒子的微观生长机理,最后对各向异性贵金属纳米粒子的应用前景做了展望。     

Alkylaminosilane‐Assisted Simultaneous Etching and Growth Route to Synthesise Metal Nanoparticles Encapsulated by Silica Nanorattles

An efficient and facile method to synthesise silica nanorattles with multiple noble metal (Au and Pd) cores by a simultaneous etching and growth route has been developed. In this strategy, a dual‐functional alkylaminosilane was adopted to form the middle layer of solid organic–inorganic hybrid solid‐silica spheres (HSSSs), which enabled the selective etching of the middle hybrid layer of the HSSSs and the in situ growth of metal nanoparticles (NPs) inside the cavity in a one‐step hydrothermal reaction. By adjusting the pH values of the reaction system, the metal NPs could be grown exclusively inside the silica nanorattles, resulting in a high atomic utilisation of the noble metals. The size and number of Au cores were tunable by manipulating the initial concentration of HAuCl₄. The prepared silica nanorattles with Au cores were successfully applied to the catalytic reduction of 4‐nitrophenol and showed high catalytic activity and cycle stability. Catalysts with multiple gold cores exhibited superior catalytic activity to those with a single gold core, probably because they possess smaller Au cores with greater surface area.     

贵金属壳-胶球核纳米复合材料的研究进展

综述了贵金属纳米粒子修饰的核胶球材料的研究进展。 由于贵金属壳-胶球核复合材料具有高的稳定性和优异的光学、催化等性质,是当前材料科学研究领域的一个热点。 因此,发展简单的、大量的制备这种复合材料的方法,以及广泛深入地研究其性能和应用具有十分重要的意义。     

多肽在贵金属纳米粒子制备中的应用

由于具有与大块固体相迥异的性能,贵金属纳米粒子的制备与应用已经成为当前纳米、材料技术领域研究的热点。由于组成成分较多、包含各种活性基团、序列可调,并且很多多肽可生物降解、生物兼容、具有生物活性和特异性识别性能,多肽在贵金属纳米粒子制备中的应用也越来越受到人们的重视。本文从多肽作为还原剂还原贵金属盐; 多肽作为保护剂/调控剂制备不同尺寸/形貌的贵金属纳米粒子; 多肽作为引导剂规则排列贵金属纳米粒子; 多肽作为贵金属纳米粒子组装的模板以及多肽在贵金属表面的吸附、多肽的自组装和如何获取所需要的多肽序列等几个方面综述了近年来多肽在贵金属纳米粒子制备中的应用。最后简述了利用多肽制备的贵金属纳米粒子在纳米、材料技术领域中的应用,并提出了当前该领域中存在的一些不足及研究展望。     

Formation of Metal Selenide and Metal–Selenium Nanoparticles using Distinct Reactivity between Selenium and Noble Metals

Small Se nanoparticles with a diameter of ≈20 nm were generated by the reduction of selenium chloride with NaBH₄ at ?10 °C. The reaction with Ag at 60 °C yielded stable Ag₂Se nanoparticles, which subsequently were transformed into M–Se nanoparticles (M=Cd, Zn, Pb) through cation exchange reactions with corresponding ions. The reaction with Pt formed Pt layers that were evenly coated on the surface of the Se nanoparticles, and the dissolution of the Se cores with hydrazine generated uniform Pt hollow nanoparticles. The reaction with Au generated tiny Au clusters on the Se surface, and eventually formed acorn‐shaped Au–Se nanoparticles through heat treatment. These results indicate that small Se nanoparticles with diameters of ≈20 nm can be used as a versatile platform for the synthesis of metal selenide and metal–selenium hybrid nanoparticles with complex structures.     

Synthesis,Structure and Light‐Harvesting Properties of Some New Transition‐Metal Dithiocarbamates Involving Ferrocene

Nine new transition‐metal dithiocarbamates involving ferrocene (Fc), namely, [M(FcCH₂Bzdtc)₂] (M=Ni^II ( 1 ), Cu^II ( 2 ), Cd^II ( 3 ), Hg^II ( 4 ), Pd^II ( 5 ), Pt^II ( 6 ) and Pb^II ( 7 ); Bzdtc=N‐benzyl dithiocarbamate) and [M(FcCH₂Bzdtc)₃] (M=Co^II ( 8 ) and UO₂^VI ( 9 )), have been synthesised and characterised by micro analyses, IR spectroscopy, ¹H and ¹³C NMR spectroscopy, and in three cases by single‐crystal X‐ray analysis. The peak broadening in the ¹H spectrum of the copper complex indicates the paramagnetic behaviour of this compound. A square‐planar geometry around the nickel and copper complexes and distorted linear geometry around the mercury complex have been found. The latter geometry is attributed to the bulkiness of the methylferrocenyl and benzyl groups. The observed single quasi‐reversible cyclic voltammograms for complexes 2 , 8 and 9 indicate the stabilisation of a metal centre other than Fe in their characteristic oxidation state. These complexes have been used as a photosensitiser in dye‐sensitised solar cells.     

贵金属纳米粒子修饰碳纳米管的研究

碳纳米管具有独特的一维管状结构和优异的电、光、热和力学性能,是药物和纳米催化剂的理想载体。将具有独特光、电、磁和催化性能的贵金属纳米粒子负载在碳纳米管的表面,形成的碳纳米管/贵金属纳米粒子复合物不仅兼有两种纳米材料的优异性能,还可能产生新的特性,在催化、储能、燃料电池、电子器件和传感器等领域均有广阔的应用前景。本文主要从共价修饰和非共价修饰两种策略出发,综述了贵金属纳米粒子修饰碳纳米管的制备方法和研究进展。其中用天然高分子包覆的碳纳米管表面具有很好的贵金属配位结合能力,得到的纳米复合物具有良好的水分散性和生物相容性,在载药、生物传感器和肿瘤诊断治疗等生物领域具有明显的优势。     

基于担载贵金属纳米粒子聚苯二胺的生物传感器

系统论述了基于聚苯二胺的电流型生物传感器,如过氧化氢传感器、葡萄糖传感器和免疫传感器等的探测性能。指出聚苯二胺中的大量氨基/亚胺基及其膜的形态结构有助于加大贵金属纳米粒子的载入量,这种载有贵金属的聚苯二胺对酶的高效锚定作用以及贵金属纳米粒子的快速电子传输能力使其具有明显的电流增敏效果。聚苯二胺膜具有优异的选择透过性能,对抗坏血酸、脲酸、醋氨酚等常见干扰物质具有较强的抗干扰能力。由此制备的生物传感器生物物质探测与分析等领域展现出了广阔的应用前景。     

Noble‐Metal Nanocrystals with Controlled Facets for Electrocatalysis

Noble‐metal nanocrystals (NCs) show excellent catalytic performance for many important electrocatalysis reactions. The crystallographic properties of the facets by which the NCs are bound, closely associated with the shape of the NCs, have a profound influence on the electrocatalytic function of the NCs. To develop an efficient strategy for the synthesis of NCs with controlled facets as well as compositions, understanding of the growth mechanism of the NCs and their interaction with the chemical species involved in NC synthesis is quite important. Furthermore, understanding the facet‐dependent catalytic properties of noble‐metal NCs and the corresponding mechanisms for various electrocatalysis reactions will allow for the rational design of robust electrocatalysts. In this review, we summarize recently developed synthesis strategies for the preparation of mono‐ and bimetallic noble‐metal NCs by classifying them by the type of facets through which they are enclosed and discuss the electrocatalytic applications of noble‐metal NCs with controlled facets, especially for reactions associated with fuel‐cell applications, such as the oxygen reduction reaction and fuel (methanol, ethanol, and formic acid) oxidation reactions.     

贵金属纳米粒子/硅纳米线复合纳米材料的制备及其催化性能研究

以十二烷基硫酸钠(SDS)作为保护剂, 利用贵金属阳离子(Mⁿ⁺)与HF处理后的硅纳米线(SiNWs)之间的氧化还原反应, 在SiNWs表面负载了贵金属纳米粒子. 通过调控SDS/Mⁿ⁺物质的量比、反应物浓度、反应温度等实验参数, 制备出了金属纳米粒子粒径均一且负载密集的AuNPs/SiNWs, PtNPs/SiNWs复合材料. 将AuNPs/SiNWs复合材料应用在亚甲基蓝的还原反应, 实验结果显示, 60 min内AuNPs/SiNWs可以将55%的亚甲基蓝还原, 表明AuNPs/SiNWs具有良好的催化活性. 这种复合材料易于从反应溶液中分离出来, 可以实现纳米催化剂的循环使用.     

Sol-Gel Preparation of Coating Films Containing Noble Metal Colloids

Coating films containing Au, Ag, Pt and Pd metal colloids have been prepared by sol-gel processing. It is shown that for oxide films the temperature where the metal particles are precipitated by heating in air depends on metal species: 200°C for Au, 600°C for Ag, 800°C for Pt and 1000°C for Pd. The use of reducing atmosphere lowers the temperature for formation of noble metal colloids. This procedure can be used for direct formation of metal colloids from metal ions in the film as well as reduction of oxide particles to metal particles in the film. For an organic-inorganic matrix, noble metal colloids are precipitated by thermal reduction or photo-reduction. Thermal reduction occurs as a result of reduction by decomposing organic matter. Photo-reduction occurs as a result of UV irradiation.     

单晶硅表面贵金属晶粒层的制备

将预处理过的单晶硅p-Si(100)浸入含贵金属盐的HF溶液, 制备了Ag, Au, Pd和Pt的晶粒层. 用原子力显微镜(AFM)、开路电位(OCP)、循环伏安(CV)和交流阻抗(A. C. Impedance)方法对晶粒层性能进行了考察. 形貌显示, 在浸镀20 s后, Ag和Pd晶粒层基本上覆盖了硅基底, Ag颗粒致密, Pd颗粒之间仍有空隙且晶粒较Ag大. Au晶粒层部分覆盖了基底, 而Pt只有极少数的晶粒. 60 s后, Ag, Pd和Au晶粒层都完全覆盖了基底, 而Pt晶粒仍然较少, 但晶粒有所长大. 循环伏安显示, Pd的溶出峰电流比Ag, Au, Pt高1个数量级. 交流阻抗测量表明, Pd晶粒层阻抗最小. 结果表明, Ag, Pd和Au都能用浸入沉积的方法在单晶硅上短时间内制备出晶粒层, 而Pt不能, 选用哪种晶粒层, 需要根据后续工序和实际需要而定.     

Promoting the Electrocatalytic Performance of Noble Metal Aerogels by Ligand‐Directed Modulation

Noble metal aerogels (NMAs) are an emerging class of porous materials. Embracing nano‐sized highly‐active noble metals and porous structures, they display unprecedented performance in diverse electrocatalytic processes. However, various impurities, particularly organic ligands, are often involved in the synthesis and remain in the corresponding products, hindering the investigation of the intrinsic electrocatalytic properties of NMAs. Here, starting from laser‐generated inorganic‐salt‐stabilized metal nanoparticles, various impurity‐free NMAs (Au, Pd, and Au‐Pd aerogels) were fabricated. In this light, we demonstrate not only the intrinsic electrocatalytic properties of NMAs, but also the prominent roles played by ligands in tuning electrocatalysis through modulating the electron density of catalysts. These findings may offer a new dimension to engineer and optimize the electrocatalytic performance for various NMAs and beyond.     

贵金属催化剂上氢气选择性催化还原NOx

NO_x的控制对于改善大气环境质量具有重要意义,而氢气选择性催化还原(H₂-SCR)NO_x作为一种高效环保的脱硝技术而备受关注。本文总结概述了近年来贵金属催化剂在H₂-SCR脱硝反应中的研究进展,首先介绍了H₂-SCR反应机理,在此基础上分别论述了影响贵金属催化剂性能的因素(如活性组分、载体类型、助剂添加及组分存在形式等)及催化剂结构与性能的构效关系。最后,针对目前存在的问题展望了H₂-SCR脱硝未来的发展方向。