Wright Cameron, Hartland Gregory V
Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, IN 46556, USA.
Photoacoustics. 2023 Mar 21;30:100476. doi: 10.1016/j.pacs.2023.100476. eCollection 2023 Apr.
The vibrational modes of semiconductor and metal nanostructures occur in the MHz to GHz frequency range, depending on dimensions. These modes are at the heart of nano-optomechanical devices, and understanding how they dissipate energy is important for applications of the devices. In this paper ultrafast transient absorption microscopy has been used to examine the breathing modes of a single gold nanoplate, where up to four overtones were observed. Analysis of the frequencies and amplitudes of the modes using a simple continuum mechanics model shows that the system behaves as a free plate, even though it is deposited onto a surface with no special preparation. The overtones decay faster than the fundamental mode, which is not predicted by continuum mechanics calculations of mode damping due to radiation of sound waves. Possible reasons for this effect include frequency dependent thermoelastic effects in the nanoplate, and/or flow of acoustic energy out of the excitation region.
半导体和金属纳米结构的振动模式发生在兆赫兹到吉赫兹的频率范围内,这取决于其尺寸。这些模式是纳米光机械设备的核心,了解它们如何耗散能量对于这些设备的应用至关重要。在本文中,超快瞬态吸收显微镜已被用于研究单个金纳米板的呼吸模式,在该研究中观察到了多达四个泛音。使用简单的连续介质力学模型对模式的频率和振幅进行分析表明,即使该金纳米板沉积在未经特殊处理的表面上,该系统的行为仍如同一个自由板。泛音的衰减比基模更快,而这一现象并未被基于声波辐射的模式阻尼连续介质力学计算所预测。这种效应的可能原因包括纳米板中与频率相关的热弹性效应,和/或声能从激发区域流出。