Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, IN 46556, USA.
College of Electronic Science and Technology, Shenzhen University, Shenzhen, 518060, P. R. China.
Nanoscale. 2019 Sep 21;11(35):16208-16213. doi: 10.1039/c9nr05940g. Epub 2019 Aug 27.
The breathing modes of single suspended gold nanoplates have been examined by transient absorption microscopy. These vibrational modes show very high quality factors which means that their frequencies can be accurately measured. Measurements performed before and after removing the organic layer that coats the as synthesized nanoplates show significant increases in frequency, which are consistent with removal of a few nm of organic material from the nanoplate surface. Experiments were also performed after depositing polymer beads on the sample. These measurements show a decrease in frequency in the region of the beads. This implies that adding a localized mass to the nanoplate hybridizes the vibrational normal modes, creating a new breathing mode which has a maximum amplitude at the bead. The nanoplate resonators have a mass sensing detection limit of ca. 10 attograms, which is comparable to the best results that have been achieved with plasmonic nanoparticles.
通过瞬态吸收显微镜研究了单个悬浮金纳米板的呼吸模式。这些振动模式的品质因数非常高,这意味着它们的频率可以被精确测量。在去除覆盖合成纳米板的有机层前后进行的测量显示出频率的显著增加,这与从纳米板表面去除几纳米的有机材料是一致的。实验还在样品上沉积聚合物珠后进行。这些测量显示在珠体区域的频率下降。这意味着向纳米板杂化添加局部质量会使振动正则模式发生杂交,从而在珠体处产生具有最大振幅的新呼吸模式。纳米板谐振器的质量传感检测极限约为 10 飞克,这与等离子体纳米粒子所达到的最佳结果相当。