Giant reversible magnetostriction in a ferromagnet-polymer composite

Thomas I. Richardson; Austin Schleusner; E. Dan Dahlberg

doi:10.1063/5.0018245

Giant reversible magnetostriction in a ferromagnet-polymer composite

Thomas I. Richardson, Austin Schleusner, E. Dan Dahlberg

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Abstract

A magnetostrictive ferromagnet-polymer composite consisting of steel wires suspended in a polymer matrix has been developed that exhibits large reversible magnetostrictive strain in relatively low magnetic fields. The strain for a fixed field is a nonmonotonic function of wire loading for the longer wires investigated, and the strain for a given wire loading increases with decreasing the wire length. Within the limits of this study, a maximum saturation strain of 60.2% in a 7.5 kOe field was observed with a wire length of 0.50 cm and a wire volume fraction of approximately 0.2. No degradation in strain was observed over the maximum number of 50 expansion cycles.

Original language	English (US)
Article number	055109
Journal	Journal of Applied Physics
Volume	128
Issue number	5
DOIs	https://doi.org/10.1063/5.0018245
State	Published - Aug 7 2020
Externally published	Yes

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abstract = "A magnetostrictive ferromagnet-polymer composite consisting of steel wires suspended in a polymer matrix has been developed that exhibits large reversible magnetostrictive strain in relatively low magnetic fields. The strain for a fixed field is a nonmonotonic function of wire loading for the longer wires investigated, and the strain for a given wire loading increases with decreasing the wire length. Within the limits of this study, a maximum saturation strain of 60.2% in a 7.5 kOe field was observed with a wire length of 0.50 cm and a wire volume fraction of approximately 0.2. No degradation in strain was observed over the maximum number of 50 expansion cycles.",

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AB - A magnetostrictive ferromagnet-polymer composite consisting of steel wires suspended in a polymer matrix has been developed that exhibits large reversible magnetostrictive strain in relatively low magnetic fields. The strain for a fixed field is a nonmonotonic function of wire loading for the longer wires investigated, and the strain for a given wire loading increases with decreasing the wire length. Within the limits of this study, a maximum saturation strain of 60.2% in a 7.5 kOe field was observed with a wire length of 0.50 cm and a wire volume fraction of approximately 0.2. No degradation in strain was observed over the maximum number of 50 expansion cycles.

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Giant reversible magnetostriction in a ferromagnet-polymer composite

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