Title
Ultrasound transmission spectroscopy: In-line sizing of nanoparticles
Author
van Neer, P.L.M.J.
Volker, A.W.F.
Pierre, G.
Bouvet, F.
Crozat, S.
Publication year
2014
Abstract
Nanoparticles are increasingly used in a number of applications, e.g. coatings or paints. To optimize nanoparticle production in-line quantitative measurements of their size distribution and concentration are needed. Ultrasound-based methods are especially suited for in-line particle sizing. These methods can be used for opaque dispersions and at high concentrations. However, using ultrasound to measure nanoparticles is challenging: despite the use of high frequencies the scattering is close to the Rayleigh regime (ka 蠐 1) and the information contained in the measurements is limited. In this work the performance of an ultrasonic particle sizing method is evaluated using SiO2 nanoparticles. The measurement method is based on ultrasound transmission spectroscopy. The presence of nanoparticles affects the propagation of ultrasound in the medium, which is measured over a frequency band of 50 - 250 MHz. The wave propagation effects are then interpreted using the inversion of a physics model. The investigated dispersions consisted of SiO2 nanoparticles (1.4 and 2.0 vol%) dispersed in water. Four batches, provided by Nano-H S.A.S., had monomodal size distributions with mean sizes 150, 300, 420 and 440 nm. Two bimodal size distributions were investigated: 1) a mix of 50% 302 nm and 50% 422 nm particles, and 2) a mix of 50% 150 nm and 50% 422 nm particles. As a reference the size distributions were measured using an optics based Malvern Zetasizer. The mean particle sizes and concentrations were similar to the reference, with differences between 4.5 and 19% and between 3 and 15%, respectively. The shape of the particle size distributions obtained by the ultrasonic instrument were similar to that of the reference. Also, the ultrasound instrument was able to produce correct results for both mono- and bimodal size distributions. The temperature of the mixture did not have a significant influence on the results.
Subject
Fluid Mechanics Chemistry & Energetics
PID - Process & Instrument Development
TS - Technical Sciences
High Tech Systems & Materials
Electronics
Industrial Innovation
Nanoparticle sizing
Transmission spectroscopy
Ultrasound spectroscopy
To reference this document use:
http://resolver.tudelft.nl/uuid:38af3a5d-9dd4-41e9-9018-4ff28970252f
TNO identifier
520216
Publisher
IEEE Computer Society
ISBN
9781479970490
ISSN
1948-5719
Source
IEEE International Ultrasonics Symposium Proceedings, 2454-2457
Article number
6932058
Document type
conference paper