SKKU Advanced Institute of Nanotechnology (SAINT), Sungkyunkwan University (SKKU), Suwon 16419, South Korea.
Nanoscale. 2017 Jun 1;9(21):7114-7123. doi: 10.1039/c7nr01462g.
Here, we systematically investigated the independent, multiple, and synergic effects of three major components, namely, ascorbic acid (AA), seed, and silver ions (Ag), on the characteristics of gold nanorods (GNRs), i.e., longitudinal localized surface plasmon resonance (LSPR) peak position, shape, size, and monodispersity. To quantitatively assess the shape and dimensions of GNRs, we used an automated transmission electron microscopy image analysis method using a MATLAB-based code developed in-house and the concept of solidity, which is the ratio between the area of a GNR and the area of its convex hull. The solidity of a straight GNR is close to 1, while it decreases for both dumbbell- and dogbone-shaped GNRs. We found that the LSPR peak position, shape, and monodispersity of the GNRs all altered simultaneously with changes in the amounts of individual components. For example, as the amount of AA increased, both the LSPR peak and solidity decreased, while the polydispersity increased. In contrast, as the amount of seeds increased, both the LSPR and solidity increased, while the monodispersity improved. More importantly, we found that the influence of each component can actually change depending on the composition of the GNR growth solution. For instance, the LSPR peak position red-shifted as the amount of AA increased when the seed content was low, whereas it blue-shifted when the seed content was high.
在这里,我们系统地研究了三种主要成分(即抗坏血酸(AA)、种子和银离子(Ag))对金纳米棒(GNR)特性(即纵向局域表面等离子体共振(LSPR)峰位置、形状、尺寸和单分散性)的独立、多重和协同影响。为了定量评估 GNR 的形状和尺寸,我们使用了一种基于 MATLAB 的自编代码的自动透射电子显微镜图像分析方法,并采用了固体率的概念,即 GNR 面积与凸包面积之比。直 GNR 的固体率接近 1,而哑铃形和狗骨形 GNR 的固体率则降低。我们发现,GNR 的 LSPR 峰位置、形状和单分散性都随着各个成分的量的变化而同时改变。例如,随着 AA 量的增加,LSPR 峰和固体率都降低,而多分散性增加。相比之下,随着种子量的增加,LSPR 和固体率都增加,而单分散性得到改善。更重要的是,我们发现每个成分的影响实际上可以根据 GNR 生长溶液的组成而变化。例如,当种子含量低时,随着 AA 量的增加,LSPR 峰位置发生红移,而当种子含量高时,LSPR 峰位置发生蓝移。
