Ternary Composite for Controlled Shape Memory Transformations

Wolfgang Hilber; Christina Offenzeller; Marcel Knoll; Herbert Enser; Bernhard Jakoby

Ternary Composite for Controlled Shape Memory Transformations

Wolfgang Hilber, Christina Offenzeller, Marcel Knoll, Herbert Enser, Bernhard Jakoby

Institute of Microelectronics and Microsensors

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

In this contribution we present an Approach towards programmable shape memory transformations utilizing the intrinsic physical properties of a ternary polymer-based composite. The underlying idea is to use an open porous elastic skeleton as the base, where the pores are filled with a component that can alter its elasticity abruptly upon an external stimulus. In this study we use PDMS as the base network, and Paraffin as the pore filler, which causes a huge change in elasticity of the composite when undergoing the solid to liquid phase change at elevated temperature. This binary composite, already featuring shape memory characteristics, is then additionally made controllable by adding nano-particles with specific Stimulus responsive properties. We demonstrate the programmable shape transformation capability of the devised ternary composite by the example of carbon black and ferromagnetic iron oxide nanoparticles.

Original language	English
Title of host publication	Proc. IEEE Sensors 2019
Number of pages	4
Publication status	Published - Oct 2019

Publication series

Name	Proc. IEEE Sensors

Fields of science

202021 Industrial electronics
202036 Sensor systems
203017 Micromechanics
202 Electrical Engineering, Electronics, Information Engineering
202027 Mechatronics
202028 Microelectronics

Cite this

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title = "Ternary Composite for Controlled Shape Memory Transformations",

abstract = "In this contribution we present an Approach towards programmable shape memory transformations utilizing the intrinsic physical properties of a ternary polymer-based composite. The underlying idea is to use an open porous elastic skeleton as the base, where the pores are filled with a component that can alter its elasticity abruptly upon an external stimulus. In this study we use PDMS as the base network, and Paraffin as the pore filler, which causes a huge change in elasticity of the composite when undergoing the solid to liquid phase change at elevated temperature. This binary composite, already featuring shape memory characteristics, is then additionally made controllable by adding nano-particles with specific Stimulus responsive properties. We demonstrate the programmable shape transformation capability of the devised ternary composite by the example of carbon black and ferromagnetic iron oxide nanoparticles.",

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AU - Offenzeller, Christina

AU - Knoll, Marcel

AU - Enser, Herbert

AU - Jakoby, Bernhard

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Y1 - 2019/10

N2 - In this contribution we present an Approach towards programmable shape memory transformations utilizing the intrinsic physical properties of a ternary polymer-based composite. The underlying idea is to use an open porous elastic skeleton as the base, where the pores are filled with a component that can alter its elasticity abruptly upon an external stimulus. In this study we use PDMS as the base network, and Paraffin as the pore filler, which causes a huge change in elasticity of the composite when undergoing the solid to liquid phase change at elevated temperature. This binary composite, already featuring shape memory characteristics, is then additionally made controllable by adding nano-particles with specific Stimulus responsive properties. We demonstrate the programmable shape transformation capability of the devised ternary composite by the example of carbon black and ferromagnetic iron oxide nanoparticles.

AB - In this contribution we present an Approach towards programmable shape memory transformations utilizing the intrinsic physical properties of a ternary polymer-based composite. The underlying idea is to use an open porous elastic skeleton as the base, where the pores are filled with a component that can alter its elasticity abruptly upon an external stimulus. In this study we use PDMS as the base network, and Paraffin as the pore filler, which causes a huge change in elasticity of the composite when undergoing the solid to liquid phase change at elevated temperature. This binary composite, already featuring shape memory characteristics, is then additionally made controllable by adding nano-particles with specific Stimulus responsive properties. We demonstrate the programmable shape transformation capability of the devised ternary composite by the example of carbon black and ferromagnetic iron oxide nanoparticles.

M3 - Conference proceedings

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BT - Proc. IEEE Sensors 2019

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