Generating and Detecting High Frequency Liquid-Based Sound Resonances with Nanoplasmonics
Yanhong Wang, Reuven Gordon

TL;DR
This paper demonstrates a novel method using nanoplasmonics and dual laser excitation to generate and detect high-frequency sound resonances in water, revealing insights into nanofluidic dynamics and potential biological implications.
Contribution
It introduces a new technique for directly exciting and measuring high-frequency sound waves in water using nanostructures and dual lasers, bridging a gap in nanofluidic research.
Findings
Observed transition from slow to fast sound in water.
Resonance frequency shifts correlate with nanostructure size.
Behavior aligns with a simple Debye model.
Abstract
We use metal nanostructures (nanoplasmonics) excited with dual frequency lasers to generate and detect high frequency (> 10 GHz) sound wave resonances in water. The difference frequency between the two lasers causes beating in the intensity, which results in a drop in the transmission through the nanostructure when an acoustic resonance is excited. By observing the resonance frequency shifts with changing nanostructure size, the transition from slow to fast sound in water is inferred, which has been measured by inelastic scattering methods in the past. The observed behavior shows remarkable similarities to a simple Debye model (without fitting parameters). The ability to directly excite high-frequency sound waves in water may unlock the secret of how the nanofluidic environment, that is typically considered to be extremely viscous, can efficiently support the energetic dynamics of life…
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