Abstract
Ultrasound constitutes a powerful means for materials processing. Similarly, a new field has emerged demonstrating the possibility for harnessing sound energy sources at considerably higher frequencies (10 MHz to 1 GHz) compared to conventional ultrasound (⩽3 MHz) for synthesizing and manipulating a variety of bulk, nanoscale, and biological materials. At these frequencies and the typical acoustic intensities employed, cavitation—which underpins most sonochemical or, more broadly, ultrasound‐mediated processes—is largely absent, suggesting that altogether fundamentally different mechanisms are at play. Examples include the crystallization of novel morphologies or highly oriented structures; exfoliation of 2D quantum dots and nanosheets; polymer nanoparticle synthesis and encapsulation; and the possibility for manipulating the bandgap of 2D semiconducting materials or the lipid structure that makes up the cell membrane, the latter resulting in the ability to enhance intracellular molecular uptake. These fascinating examples reveal how the highly nonlinear electromechanical coupling associated with such high‐frequency surface vibration gives rise to a variety of static and dynamic charge generation and transfer effects, in addition to molecular ordering, polarization, and assembly—remarkably, given the vast dimensional separation between the acoustic wavelength and characteristic molecular length scales, or between the MHz‐order excitation frequencies and typical THz‐order molecular vibration frequencies.
Highlights
Ultrasound constitutes a powerful means for materials processing
Examples include the crystallization of novel morphologies or highly oriented structures; exfoliation of 2D quantum dots and nanosheets; polymer nanoparticle synthesis and encapsulation; and the possibility for manipulating the bandgap of 2D semiconducting materials or nanoparticle production through flash nanoprecipitation[7]), the predominant mechanism responsible for the majority of sonochemical synthesis can largely be attributed to acoustic cavitation.[8,9,10,11]
Unlike cavitationdriven sonolytic water splitting,[32] the dissociation of the water molecules was shown to be a consequence of the strong electromechanical coupling associated with the propagation of the acoustic wave on the piezoelectric substrate, whose evanescent electric field will be seen subsequently to be responsible for a host of other phenomena related to materials synthesis, processing, and manipulation
Summary
Materials Synthesis Driven by Cavitation macroscopic acoustic streaming scales, commensurate with the length scales over which the acoustic energy dissipates.[14,15,16,17,18,19]. Where chemical reactions are involved, cavitation-driven microstreaming, for example, has been employed for mixing,[20] dispersion,[21] emulsification,[22]. Www.advancedsciencenews.com www.advancedscience.com polymerization,[37] electrodeposition,[38] and the degradation of organic compounds.[39]
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