Importance of acoustic shielding in sonochemistry

Maikel M. van Iersel; Nieck E. Benes; Jos T.F. Keurentjes

doi:10.1016/j.ultsonch.2007.09.015

Importance of acoustic shielding in sonochemistry

Maikel M. van Iersel
, Nieck E. Benes^*
, Jos T.F. Keurentjes

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

74 Citations (Scopus)

Abstract

It is well known that sonochemistry is less efficient at high acoustic intensities. Many authors have attributed this effect to decoupling losses and shielding of the acoustic wave. In this study we investigate both phenomena for a 20 kHz ultrasound field with an intensity ranging from 40 to 150 W/cm². Visualization of the bubble cloud has demonstrated that the void fraction below the ultrasound horn increases more than proportional with increasing power input. Nevertheless, the energy coupling between the horn and the liquid remains constant; this implies that decoupling losses are not reinforced for larger bubble clouds. On the contrary, microphone measurements have shown that due to the larger bubble cloud a substantial part of the supplied energy is lost at high power inputs. In striving towards more efficient sonochemistry, reduction of shielding appears as one of the major challenges.

Original language	English
Pages (from-to)	294-300
Number of pages	7
Journal	Ultrasonics sonochemistry
Volume	15
Issue number	4
DOIs	https://doi.org/10.1016/j.ultsonch.2007.09.015
Publication status	Published - Apr 2008
Externally published	Yes

Keywords

n/a OA procedure
Decoupling
Sonochemistry
Sound attenuation
Ultrasound power
Bubble cloud

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10.1016/j.ultsonch.2007.09.015

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title = "Importance of acoustic shielding in sonochemistry",

abstract = "It is well known that sonochemistry is less efficient at high acoustic intensities. Many authors have attributed this effect to decoupling losses and shielding of the acoustic wave. In this study we investigate both phenomena for a 20 kHz ultrasound field with an intensity ranging from 40 to 150 W/cm2. Visualization of the bubble cloud has demonstrated that the void fraction below the ultrasound horn increases more than proportional with increasing power input. Nevertheless, the energy coupling between the horn and the liquid remains constant; this implies that decoupling losses are not reinforced for larger bubble clouds. On the contrary, microphone measurements have shown that due to the larger bubble cloud a substantial part of the supplied energy is lost at high power inputs. In striving towards more efficient sonochemistry, reduction of shielding appears as one of the major challenges.",

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AU - van Iersel, Maikel M.

AU - Benes, Nieck E.

AU - Keurentjes, Jos T.F.

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N2 - It is well known that sonochemistry is less efficient at high acoustic intensities. Many authors have attributed this effect to decoupling losses and shielding of the acoustic wave. In this study we investigate both phenomena for a 20 kHz ultrasound field with an intensity ranging from 40 to 150 W/cm2. Visualization of the bubble cloud has demonstrated that the void fraction below the ultrasound horn increases more than proportional with increasing power input. Nevertheless, the energy coupling between the horn and the liquid remains constant; this implies that decoupling losses are not reinforced for larger bubble clouds. On the contrary, microphone measurements have shown that due to the larger bubble cloud a substantial part of the supplied energy is lost at high power inputs. In striving towards more efficient sonochemistry, reduction of shielding appears as one of the major challenges.

AB - It is well known that sonochemistry is less efficient at high acoustic intensities. Many authors have attributed this effect to decoupling losses and shielding of the acoustic wave. In this study we investigate both phenomena for a 20 kHz ultrasound field with an intensity ranging from 40 to 150 W/cm2. Visualization of the bubble cloud has demonstrated that the void fraction below the ultrasound horn increases more than proportional with increasing power input. Nevertheless, the energy coupling between the horn and the liquid remains constant; this implies that decoupling losses are not reinforced for larger bubble clouds. On the contrary, microphone measurements have shown that due to the larger bubble cloud a substantial part of the supplied energy is lost at high power inputs. In striving towards more efficient sonochemistry, reduction of shielding appears as one of the major challenges.

KW - n/a OA procedure

KW - Decoupling

KW - Sonochemistry

KW - Sound attenuation

KW - Ultrasound power

KW - Bubble cloud

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JO - Ultrasonics sonochemistry

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Importance of acoustic shielding in sonochemistry

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Keywords

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