Ultrasound attenuation in ferrofluids

Mark Shliomis; Michael Mond; Konstantin Morozov

doi:10.1103/PhysRevLett.101.074505

Ultrasound attenuation in ferrofluids

Mark Shliomis
, Michael Mond
, Konstantin Morozov

Department of Mechanical Engineering

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

25 Scopus citations

Abstract

The absorption of acoustic energy by internal degrees of freedom of short chains is proposed as a new viable mechanism of ultrasound attenuation in ferrofluids. It is demonstrated that even though the volume fraction of the chains may be quite small, such an effect may reach the order of magnitude of viscous damping. In addition, by investigating the statistical properties of dimers in ferrofluids, it is shown that an applied magnetic field modifies the sound attenuation in a highly anisotropic manner. The proposed mechanism provides new insight into the fundamental issue of colloidal response, and, in particular, may lead to its utilization in novel experimental concepts.

Original language	English
Article number	074505
Journal	Physical Review Letters
Volume	101
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevLett.101.074505
State	Published - 15 Aug 2008

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.101.074505

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abstract = "The absorption of acoustic energy by internal degrees of freedom of short chains is proposed as a new viable mechanism of ultrasound attenuation in ferrofluids. It is demonstrated that even though the volume fraction of the chains may be quite small, such an effect may reach the order of magnitude of viscous damping. In addition, by investigating the statistical properties of dimers in ferrofluids, it is shown that an applied magnetic field modifies the sound attenuation in a highly anisotropic manner. The proposed mechanism provides new insight into the fundamental issue of colloidal response, and, in particular, may lead to its utilization in novel experimental concepts.",

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AB - The absorption of acoustic energy by internal degrees of freedom of short chains is proposed as a new viable mechanism of ultrasound attenuation in ferrofluids. It is demonstrated that even though the volume fraction of the chains may be quite small, such an effect may reach the order of magnitude of viscous damping. In addition, by investigating the statistical properties of dimers in ferrofluids, it is shown that an applied magnetic field modifies the sound attenuation in a highly anisotropic manner. The proposed mechanism provides new insight into the fundamental issue of colloidal response, and, in particular, may lead to its utilization in novel experimental concepts.

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Ultrasound attenuation in ferrofluids

Abstract

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