Size of liquid metal particles influences actuation properties of a liquid crystal elastomer composite

Size of liquid metal particles influences actuation properties of a liquid crystal elastomer composite

Composites of liquid crystal elastomer (LCE) that are electrically conductive have the potential to function as soft "artificial muscle" actuators that can be reversibly stimulated with electrical Joule-heating. Conductivity can be achieved by embedding the LCE with droplets of an alloy of...

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Veröffentlicht in:Soft matter 2020-07, Vol.16 (25), p.5878-5885
Hauptverfasser: Ford, Michael J, Palaniswamy, Maduran, Ambulo, Cedric P, Ware, Taylor H, Majidi, Carmel
Format: Artikel
Sprache:eng
Schlagworte:
Actuation
Actuators
Artificial muscles
Casting
Droplets
Elastomers
Electrical resistivity
Embedding
Fabrication
Gallium
Gallium base alloys
Indium
Liquid crystals
Liquid metals
Metal particles
Metals
Muscle contraction
Muscles
Particulate composites
Properties (attributes)
Room temperature
Strain
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container_end_page 5885
container_issue 25
container_start_page 5878
container_title Soft matter
container_volume 16
creator Ford, Michael J
Palaniswamy, Maduran
Ambulo, Cedric P
Ware, Taylor H
Majidi, Carmel
description Composites of liquid crystal elastomer (LCE) that are electrically conductive have the potential to function as soft "artificial muscle" actuators that can be reversibly stimulated with electrical Joule-heating. Conductivity can be achieved by embedding the LCE with droplets of an alloy of gallium and indium that is liquid at room temperature. These soft artificial muscles are capable of >50% reversible actuation with an applied load. The key to actuation at high loadings of liquid metal (LM) is that the droplets deform with the surrounding matrix. By controlling the size of LM droplets through simple processing techniques, we show that the actuator properties of the LM-LCE muscle can be tuned. For example, composites with smaller liquid metal particles ( ca. 10 μm or less) are stiffer than those with larger liquid metal particles ( ca. >100 μm) and are capable of greater force output. However, smaller particles reduce actuation strain and composites with large particles exhibit significantly greater stroke length. Such tunability in actuation properties permits the fabrication of specialized soft artificial muscles, where processing of the composite controls actuation strain and actuation force. A shape-morphing composite exhibits tunable actuation properties (stroke and force output) that are influenced by liquid metal particle size.
doi_str_mv 10.1039/d0sm00278j
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source Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects Actuation
Actuators
Artificial muscles
Casting
Droplets
Elastomers
Electrical resistivity
Embedding
Fabrication
Gallium
Gallium base alloys
Indium
Liquid crystals
Liquid metals
Metal particles
Metals
Muscle contraction
Muscles
Particulate composites
Properties (attributes)
Room temperature
Strain
title Size of liquid metal particles influences actuation properties of a liquid crystal elastomer composite
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