光刺激合成贵金属纳米颗粒

S. Drapak, A. Ivanova-Tolpintseva, Y. Khalavka
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引用次数: 0

摘要

如今,现代材料科学最相关的领域之一是纳米粒子和纳米材料科学,以及纳米技术。纳米材料在纳米尺度上的组成、尺寸和形状决定了其电子、光学、磁性、催化等性能。由于其独特的光学和催化性能,贵金属纳米粒子(银和金纳米粒子)是当今研究最深入的纳米物体之一。银和金纳米颗粒的性质在电子、光学、太阳能、信息存储、通信、生物医学、环境研究等领域具有极其重要的技术应用前景。贵金属纳米粒子的许多有前途的应用是由于局域表面等离子体共振的影响,它是由导电电子相对于由纳米粒子表面的金属晶格中的离子在共振激发频率下的集体振荡组成的。纳米粒子基本物理化学性质的尺寸依赖性对合成提出了特定的要求,必须提供必要的颗粒直径和尺寸分布、表面功能化的可能性、颗粒在制造过程中的稳定性以及后续的储存和操作,以供其进一步实际应用。现有的获得贵金属纳米颗粒的方法,包括物理、热、化学、光化学、电化学等,不能提供所需的可重复性,或者对于大规模使用来说太昂贵。此外,目前已知的大多数方法只能获得形状和尺寸分布广泛的金属纳米颗粒。仔细控制反应参数,如时间、工艺温度、搅拌速率、反应物浓度和稳定添加剂,可以缩小纳米颗粒的尺寸分布,但并不总是达到期望的极限。根据最近的研究,在反应混合物中激发等离子体激发反应可以得到单分散的贵金属纳米粒子胶体溶液。本综述基于一系列实验研究,展示了如何利用光来控制贵金属纳米颗粒的生长、形状和大小过程,并将非均质金属纳米颗粒群体转化为具有高单分散性的群体。考虑了不同尺寸和形状的金属纳米粒子在光谱中的局域表面等离子体的表现。此外,还讨论了与金属纳米颗粒中局部表面等离子体共振激发相关的光物理过程,该过程允许在纳米尺度上控制化学反应,即光热效应;纳米粒子表面附近的光集中,导致电磁场和粒子附近分子的光子通量强度增加,并产生热电子-空穴对,参与纳米粒子和附近分子之间的电荷转移。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Photostimulated Synthesis of Noble Metals Nanoparticles
Nowadays, one of the most relevant areas of modern materials science is the science of nanoparticles and nanomaterials, as well as nanotechnology. Composition, size and shape of nanomaterials at the nanoscale determines its electronic, optical, magnetic, catalytic, etc. properties. Due to the unique optical and catalytic properties, noble metals nanoparticles (silver and gold ones) today are one of the most intensively studied types of nanoobjects. The properties of silver and gold nanoparticles are extremely important and promising for technological use in such areas as electronics, optics, solar energy, information storage, communications, biomedicine, environmental research and others. A number of promising applications of noble metal nanoparticles are due to the effect of localized surface plasmon resonance, which consists in the collective oscillation of conduction electrons relatively to the ions in metallic crystal lattice bounded by the nanoparticle surface at the resonant excitation frequency. The dimensional dependence of the basic physical and chemical properties of nanoparticles makes specific demands on the synthesis, which should provide the necessary particles’ diameter and size distribution, the possibility of surface functionalization, particles’ stability in the manufacturing process, subsequent storage and operation for its further practical application. Existing methods for obtaining noble metals nanoparticles, including physical, thermal, chemical, photochemical, electrochemical, etc. do not provide the required reproducibility or are too expensive for mass use. In addition, most currently known methods allow to obtain metal nanoparticles only with a wide distribution of shapes and sizes. Careful control of the reaction parameters, such as time, process temperature, stirring rate, concentration of reactans and stabilizing additives, allows to narrow the size distribution of nanoparticles, but not always to the desired limits. According to recent studies, monodisperse colloidal solutions of noble metals nanoparticles can be obtained by excitation of plasmon-stimulated reactions in the reaction mixture. This review, based on a rage of experimental studies, demonstrates how light can be used to control the processes of growth, shape and size of noble metals nanoparticles, and to convert heterogeneous populations of metal nanoparticles into populations with high monodispersity. The manifestation of localized surface plasmons in the optical spectra of metal nanoparticles of different sizes and shapes was also considered. In addition, there were also discussed photophysical processes, associated with the excitation of localized surface plasmon resonance in metal nanoparticles, which allow to control chemical reactions at the nanoscale, namely the photothermal effect; concentration of light near the surface of nanoparticles, which leads to an increase in the electromagnetic field and the intensity of the photon flux for molecules near the particles and the generation of hot electron-hole pairs that can participate in charge transfer between nanoparticles and nearby molecules.
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