Impact of high-frequency ultrasound on nanocomposite microcapsules: in silico and in situ visualization

Impact of high-frequency ultrasound on nanocomposite microcapsules: in silico and in situ visualization

The impact of high-frequency (1.2 MHz) ultrasound with a power density of 0.33 W cm(-2) on microcapsule nanocomposite shells with embedded zinc oxide nanoparticles was investigated by exploring modeling simulations and direct visualization. For the first time the sonication effect has been monitored...

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Veröffentlicht in:Physical chemistry chemical physics : PCCP 2016-01, Vol.18 (4), p.2389-2397
Hauptverfasser: Korolovych, V F, Grishina, O A, Inozemtseva, O A, Selifonov, A V, Bratashov, D N, Suchkov, S G, Bulavin, L A, Glukhova, O E, Sukhorukov, G B, Gorin, D A
Format: Artikel
Sprache:eng
Schlagworte:
Computer simulation
Low frequencies
Nanocomposites
Nanoparticles
Physical chemistry
Stress concentration
Stress distribution
Ultrasound
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Zusammenfassung:The impact of high-frequency (1.2 MHz) ultrasound with a power density of 0.33 W cm(-2) on microcapsule nanocomposite shells with embedded zinc oxide nanoparticles was investigated by exploring modeling simulations and direct visualization. For the first time the sonication effect has been monitored in situ on individual microcapsules upon exposure of their aqueous suspension to ultrasound. The stress distribution on the microcapsule shell for the impact of ultrasound with high (1.2 MHz) and low (20 kHz) frequency at two fixed intensities (0.33 and 30 W cm(-2)) has been modeled. As shown in silico and experimentally the nanocomposite microcapsules were destroyed more effectively by the action of high-frequency (1.2 MHz) ultrasound in comparison to the low frequency (20 kHz) one with the same power density.
ISSN:1463-9076
1463-9084
DOI:10.1039/c5cp05465f