Harnessing snap-through instability in soft dielectrics to achieve giant voltage-triggered deformation

Christoph Keplinger; Tiefeng Li; Richard Baumgartner; Zhigang Suo; Siegfried Bauer

doi:10.1039/c1sm06736b

Harnessing snap-through instability in soft dielectrics to achieve giant voltage-triggered deformation

Christoph Keplinger
, Tiefeng Li
, Richard Baumgartner
, Zhigang Suo
, Siegfried Bauer

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

414 Scopus citations

Abstract

A soft dielectric membrane is prone to snap-through instability. We present theory and experiment to show that the instability can be harnessed to achieve giant voltage-triggered deformation. We mount a membrane on a chamber of a suitable volume, pressurize the membrane into a state near the verge of the instability, and apply a voltage to trigger the snap without causing electrical breakdown. For an acrylic membrane we demonstrate voltage-triggered expansion of area by 1692%, far beyond the largest value reported in the literature. The large expansion can even be retained after the voltage is switched off.

Original language	English
Pages (from-to)	285-288
Number of pages	4
Journal	Soft Matter
Volume	8
Issue number	2
DOIs	https://doi.org/10.1039/c1sm06736b
State	Published - 14 Jan 2012
Externally published	Yes

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abstract = "A soft dielectric membrane is prone to snap-through instability. We present theory and experiment to show that the instability can be harnessed to achieve giant voltage-triggered deformation. We mount a membrane on a chamber of a suitable volume, pressurize the membrane into a state near the verge of the instability, and apply a voltage to trigger the snap without causing electrical breakdown. For an acrylic membrane we demonstrate voltage-triggered expansion of area by 1692\%, far beyond the largest value reported in the literature. The large expansion can even be retained after the voltage is switched off.",

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AU - Keplinger, Christoph

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AU - Bauer, Siegfried

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N2 - A soft dielectric membrane is prone to snap-through instability. We present theory and experiment to show that the instability can be harnessed to achieve giant voltage-triggered deformation. We mount a membrane on a chamber of a suitable volume, pressurize the membrane into a state near the verge of the instability, and apply a voltage to trigger the snap without causing electrical breakdown. For an acrylic membrane we demonstrate voltage-triggered expansion of area by 1692%, far beyond the largest value reported in the literature. The large expansion can even be retained after the voltage is switched off.

AB - A soft dielectric membrane is prone to snap-through instability. We present theory and experiment to show that the instability can be harnessed to achieve giant voltage-triggered deformation. We mount a membrane on a chamber of a suitable volume, pressurize the membrane into a state near the verge of the instability, and apply a voltage to trigger the snap without causing electrical breakdown. For an acrylic membrane we demonstrate voltage-triggered expansion of area by 1692%, far beyond the largest value reported in the literature. The large expansion can even be retained after the voltage is switched off.

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Harnessing snap-through instability in soft dielectrics to achieve giant voltage-triggered deformation

Abstract

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