Nanoparticle sizing by focused-beam dynamic ultrasound scattering method

•Nanoparticle sizing was performed using dynamic ultrasound scattering technique.•Sample thickness was made thinner to suppress unfavorable acoustic flow.•The technique discriminated mixtures of nanoparticles by different relaxation time. When nanoparticles in Brownian motion in liquid are irradiate...

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Bibliographic Details
Published in:Ultrasonics 2022-12, Vol.126, p.106807-106807, Article 106807
Main Authors: Kitao, Kana, Norisuye, Tomohisa
Format: Article
Language:English
Subjects:
Particle sizing
Scattering
Ultrasound
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Summary:•Nanoparticle sizing was performed using dynamic ultrasound scattering technique.•Sample thickness was made thinner to suppress unfavorable acoustic flow.•The technique discriminated mixtures of nanoparticles by different relaxation time. When nanoparticles in Brownian motion in liquid are irradiated with ultrasonic waves in the megahertz frequency range, scattering from the particles occurs, albeit at a very low intensity. The diffusion coefficient and the corresponding particle size can be calculated by analyzing the time correlation function of the ultrasound pulses. Since ultrasonic waves with long wavelengths in comparison with the particle size are unfavorable for detecting such small particles, increasing the energy of the ultrasonic waves is a primary solution. Increasing the energy, conversely, causes an unexpected acoustic flow. Consequently, a method using a strong ultrasound pulse while suppressing this acoustic flow field is required. In this study, we apply (1) a focused transducer with high ultrasonic energy, (2) a high-frequency sensor enhancing scattering performance, and (3) a short pulse repetition time to achieve high-speed and high-precision nanoparticle measurement while confining the sample in a narrow space to eliminate the acoustic flow. This enables direct tracking of nanoparticle motion by observing diffusive motion without perturbation particle dynamics. We specifically investigated a suspension of silica particles with a hydrodynamic radius of 15 nm and also achieved particle size discrimination in mixtures. The time correlation analysis using megahertz ultrasound pulses also takes advantage of ultrasonic waves’ inherent advantages, such as high-speed, high-precision particle size analysis in the submicron range beyond the wavelength of visible light.
ISSN:0041-624X
1874-9968
DOI:10.1016/j.ultras.2022.106807