posted on 2013-03-19, 00:00authored byJeremy Blamey, Leslie
Y. Yeo, James R. Friend
Low frequency (O(10 Hz–10 kHz)) vibration
excitation of capillary waves has been extensively studied for nearly
two centuries. Such waves appear at the excitation frequency or at
rational multiples of the excitation frequency through nonlinear coupling
as a result of the finite displacement of the wave, most often at
one-half the excitation frequency in so-called Faraday waves and twice
this frequency in superharmonic waves. Less understood, however, are
the dynamics of capillary waves driven by high-frequency vibration
(>O(100 kHz)) and small interface length scales,
an arrangement ideal for a broad variety of applications, from nebulizers
for pulmonary drug delivery to complex nanoparticle synthesis. In
the few studies conducted to date, a marked departure from the predictions
of classical Faraday wave theory has been shown, with the appearance
of broadband capillary wave generation from 100 Hz to the excitation
frequency and beyond, without a clear explanation. We show that weak
wave turbulence is the dominant mechanism in the behavior of the system,
as evident from wave height frequency spectra that closely follow
the Rayleigh–Jeans spectral response η ≈ ω–17/12 as a consequence of a period-halving, weakly
turbulent cascade that appears within a 1 mm water drop whether driven
by thickness-mode or surface acoustic Rayleigh wave excitation. However,
such a cascade is one-way, from low to high frequencies. The mechanism
of exciting the cascade with high-frequency acoustic waves is an acoustic
streaming-driven turbulent jet in the fluid bulk, driving the fundamental
capillary wave resonance through the well-known coupling between bulk
flow and surface waves. Unlike capillary waves, turbulent acoustic
streaming can exhibit subharmonic cascades from high to low frequencies;
here it appears from the excitation frequency all the way to the fundamental
modes of the capillary wave at some four orders of magnitude in frequency
less than the excitation frequency, enabling the capillary weakly
turbulent wave cascade to form from the fundamental capillary wave
upward.