Electric Field Driven Soft Morphing Matter

Ciqun Xu; Charl F. J. Faul; Majid Taghavi; Jonathan Rossiter

doi:10.1002/adma.202419077

Electric Field Driven Soft Morphing Matter

Ciqun Xu, Charl F. J. Faul, Majid Taghavi^*, Jonathan Rossiter^*

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

The manipulation of soft morphing robots using external electric fields and wireless control is challenging. Electric field‐driven soft morphing matter, termed electro‐morphing gel (e‐MG), that exhibits complex multimodal large‐scale deformation (showing up to 286% strain, and strain rates up to 500% s−1) and locomotion under external electric fields applied using compact and lightweight electrodes is presented. The distinctive capabilities of e‐MG derive from the combination of an elastomeric matrix and nanoparticulate paracrystalline carbon. The material properties, electroactive principle, and control strategies are explored and demonstrate fundamental morphing matter behaviors including rotating, translating, stretching, spreading, bending, and twisting. A range of potential bio‐inspired applications, including slim mold‐like spreading, snail‐like jumping over a gap, object transport, wall climbing, and a frog tongue‐inspired gripper is shown. The e‐MG provides morphing capabilities beyond the current limitations in wireless control for a wide range of applications in soft and bio‐inspired robotics, dexterous manipulation, and space exploration.

Original language	English
Article number	2419077
Number of pages	13
Journal	Advanced Materials
Volume	37
Issue number	41
Early online date	12 Jun 2025
DOIs	https://doi.org/10.1002/adma.202419077
Publication status	Published - 16 Oct 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Advanced Materials published by Wiley-VCH GmbH.

Research Groups and Themes

Inorganic & Materials

Keywords

soft robots
electric field actuation
electroactive material
bio‐inspired actuation
shape‐morphing gel

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title = "Electric Field Driven Soft Morphing Matter",

abstract = "The manipulation of soft morphing robots using external electric fields and wireless control is challenging. Electric field‐driven soft morphing matter, termed electro‐morphing gel (e‐MG), that exhibits complex multimodal large‐scale deformation (showing up to 286\% strain, and strain rates up to 500\% s−1) and locomotion under external electric fields applied using compact and lightweight electrodes is presented. The distinctive capabilities of e‐MG derive from the combination of an elastomeric matrix and nanoparticulate paracrystalline carbon. The material properties, electroactive principle, and control strategies are explored and demonstrate fundamental morphing matter behaviors including rotating, translating, stretching, spreading, bending, and twisting. A range of potential bio‐inspired applications, including slim mold‐like spreading, snail‐like jumping over a gap, object transport, wall climbing, and a frog tongue‐inspired gripper is shown. The e‐MG provides morphing capabilities beyond the current limitations in wireless control for a wide range of applications in soft and bio‐inspired robotics, dexterous manipulation, and space exploration.",

keywords = "soft robots, electric field actuation, electroactive material, bio‐inspired actuation, shape‐morphing gel",

author = "Ciqun Xu and Faul, \{Charl F. J.\} and Majid Taghavi and Jonathan Rossiter",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Materials published by Wiley-VCH GmbH.",

year = "2025",

month = oct,

day = "16",

doi = "10.1002/adma.202419077",

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AU - Xu, Ciqun

AU - Faul, Charl F. J.

AU - Taghavi, Majid

AU - Rossiter, Jonathan

PY - 2025/10/16

Y1 - 2025/10/16

N2 - The manipulation of soft morphing robots using external electric fields and wireless control is challenging. Electric field‐driven soft morphing matter, termed electro‐morphing gel (e‐MG), that exhibits complex multimodal large‐scale deformation (showing up to 286% strain, and strain rates up to 500% s−1) and locomotion under external electric fields applied using compact and lightweight electrodes is presented. The distinctive capabilities of e‐MG derive from the combination of an elastomeric matrix and nanoparticulate paracrystalline carbon. The material properties, electroactive principle, and control strategies are explored and demonstrate fundamental morphing matter behaviors including rotating, translating, stretching, spreading, bending, and twisting. A range of potential bio‐inspired applications, including slim mold‐like spreading, snail‐like jumping over a gap, object transport, wall climbing, and a frog tongue‐inspired gripper is shown. The e‐MG provides morphing capabilities beyond the current limitations in wireless control for a wide range of applications in soft and bio‐inspired robotics, dexterous manipulation, and space exploration.

AB - The manipulation of soft morphing robots using external electric fields and wireless control is challenging. Electric field‐driven soft morphing matter, termed electro‐morphing gel (e‐MG), that exhibits complex multimodal large‐scale deformation (showing up to 286% strain, and strain rates up to 500% s−1) and locomotion under external electric fields applied using compact and lightweight electrodes is presented. The distinctive capabilities of e‐MG derive from the combination of an elastomeric matrix and nanoparticulate paracrystalline carbon. The material properties, electroactive principle, and control strategies are explored and demonstrate fundamental morphing matter behaviors including rotating, translating, stretching, spreading, bending, and twisting. A range of potential bio‐inspired applications, including slim mold‐like spreading, snail‐like jumping over a gap, object transport, wall climbing, and a frog tongue‐inspired gripper is shown. The e‐MG provides morphing capabilities beyond the current limitations in wireless control for a wide range of applications in soft and bio‐inspired robotics, dexterous manipulation, and space exploration.

KW - soft robots

KW - electric field actuation

KW - electroactive material

KW - bio‐inspired actuation

KW - shape‐morphing gel

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DO - 10.1002/adma.202419077

M3 - Article (Academic Journal)

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SN - 0935-9648

VL - 37

JO - Advanced Materials

JF - Advanced Materials

IS - 41

M1 - 2419077

ER -

Electric Field Driven Soft Morphing Matter

Abstract

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