Instant tough bonding of hydrogels for soft machines and electronics

Daniela Wirthl; Robert Pichler; Michael Drack; Gerald Kettlgruber; Richard Moser; Robert Gerstmayr; Florian Hartmann; Elke Bradt; Rainer Kaltseis; Christian Siket; Stefan Schausberger; Sabine Hild; Siegfried Bauer; Martin Kaltenbrunner

doi:10.1126/sciadv.1700053

Instant tough bonding of hydrogels for soft machines and electronics

Daniela Wirthl
, Robert Pichler
, Michael Drack
, Gerald Kettlgruber
, Richard Moser
, Robert Gerstmayr
, Florian Hartmann
, Elke Bradt
, Rainer Kaltseis
, Christian Siket
, Stefan Schausberger
, Sabine Hild
, Siegfried Bauer
, Martin Kaltenbrunner

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

Abstract

Introducing methods for instant tough bonding between hydrogels and antagonistic materials - from soft to hard - allows us to demonstrate elastic yet tough biomimetic devices and machines with a high level of complexity. Tough hydrogels strongly attach, within seconds, to plastics, elastomers, leather, bone, and metals, reaching unprecedented interfacial toughness exceeding 2000 J/m2. Healing of severed ionic hydrogel conductors becomes feasible and restores function instantly. Soft, transparent multilayered hybrids of elastomers and ionic hydrogels endure biaxial strain with more than 2000% increase in area, facilitating soft transducers, generators, and adaptive lenses. We demonstrate soft electronic devices, from stretchable batteries, self-powered compliant circuits, and autonomous electronic skin for triggered drug delivery. Our approach is applicable in rapid prototyping and in delicate environments inaccessible for extended curing and cross-linking.

Original language	English
Article number	e1700053
Number of pages	9
Journal	Science Advances
Volume	3
Issue number	6
DOIs	https://doi.org/10.1126/sciadv.1700053
Publication status	Published - Jun 2017

Fields of science

205016 Materials testing
210002 Nanobiotechnology
210006 Nanotechnology
103 Physics, Astronomy
103023 Polymer physics
104 Chemistry
104004 Chemical biology
104018 Polymer chemistry
205012 Polymer processing
206001 Biomedical engineering
211905 Bionics
104017 Physical chemistry
104019 Polymer sciences
103008 Experimental physics
301207 Pharmaceutical chemistry
104002 Analytical chemistry
204002 Chemical reaction engineering
301305 Medical chemistry
104015 Organic chemistry
104014 Surface chemistry
104011 Materials chemistry
104010 Macromolecular chemistry
104008 Catalysis
210004 Nanomaterials
104016 Photochemistry
301904 Cancer research
107002 Bionics
302009 Chemotherapy
304007 Tissue engineering
106002 Biochemistry

JKU Focus areas

Nano-, Bio- and Polymer-Systems: From Structure to Function
Engineering and Natural Sciences (in general)
Sustainable Development: Responsible Technologies and Management
Digital Transformation

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10.1126/sciadv.1700053

Cite this

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title = "Instant tough bonding of hydrogels for soft machines and electronics",

abstract = "Introducing methods for instant tough bonding between hydrogels and antagonistic materials - from soft to hard - allows us to demonstrate elastic yet tough biomimetic devices and machines with a high level of complexity. Tough hydrogels strongly attach, within seconds, to plastics, elastomers, leather, bone, and metals, reaching unprecedented interfacial toughness exceeding 2000 J/m2. Healing of severed ionic hydrogel conductors becomes feasible and restores function instantly. Soft, transparent multilayered hybrids of elastomers and ionic hydrogels endure biaxial strain with more than 2000\% increase in area, facilitating soft transducers, generators, and adaptive lenses. We demonstrate soft electronic devices, from stretchable batteries, self-powered compliant circuits, and autonomous electronic skin for triggered drug delivery. Our approach is applicable in rapid prototyping and in delicate environments inaccessible for extended curing and cross-linking.",

author = "Daniela Wirthl and Robert Pichler and Michael Drack and Gerald Kettlgruber and Richard Moser and Robert Gerstmayr and Florian Hartmann and Elke Bradt and Rainer Kaltseis and Christian Siket and Stefan Schausberger and Sabine Hild and Siegfried Bauer and Martin Kaltenbrunner",

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month = jun,

doi = "10.1126/sciadv.1700053",

language = "English",

volume = "3",

journal = "Science Advances",

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T1 - Instant tough bonding of hydrogels for soft machines and electronics

AU - Wirthl, Daniela

AU - Pichler, Robert

AU - Drack, Michael

AU - Kettlgruber, Gerald

AU - Moser, Richard

AU - Gerstmayr, Robert

AU - Hartmann, Florian

AU - Bradt, Elke

AU - Kaltseis, Rainer

AU - Siket, Christian

AU - Schausberger, Stefan

AU - Hild, Sabine

AU - Bauer, Siegfried

AU - Kaltenbrunner, Martin

PY - 2017/6

Y1 - 2017/6

N2 - Introducing methods for instant tough bonding between hydrogels and antagonistic materials - from soft to hard - allows us to demonstrate elastic yet tough biomimetic devices and machines with a high level of complexity. Tough hydrogels strongly attach, within seconds, to plastics, elastomers, leather, bone, and metals, reaching unprecedented interfacial toughness exceeding 2000 J/m2. Healing of severed ionic hydrogel conductors becomes feasible and restores function instantly. Soft, transparent multilayered hybrids of elastomers and ionic hydrogels endure biaxial strain with more than 2000% increase in area, facilitating soft transducers, generators, and adaptive lenses. We demonstrate soft electronic devices, from stretchable batteries, self-powered compliant circuits, and autonomous electronic skin for triggered drug delivery. Our approach is applicable in rapid prototyping and in delicate environments inaccessible for extended curing and cross-linking.

AB - Introducing methods for instant tough bonding between hydrogels and antagonistic materials - from soft to hard - allows us to demonstrate elastic yet tough biomimetic devices and machines with a high level of complexity. Tough hydrogels strongly attach, within seconds, to plastics, elastomers, leather, bone, and metals, reaching unprecedented interfacial toughness exceeding 2000 J/m2. Healing of severed ionic hydrogel conductors becomes feasible and restores function instantly. Soft, transparent multilayered hybrids of elastomers and ionic hydrogels endure biaxial strain with more than 2000% increase in area, facilitating soft transducers, generators, and adaptive lenses. We demonstrate soft electronic devices, from stretchable batteries, self-powered compliant circuits, and autonomous electronic skin for triggered drug delivery. Our approach is applicable in rapid prototyping and in delicate environments inaccessible for extended curing and cross-linking.

UR - https://www.scopus.com/pages/publications/85032296372

U2 - 10.1126/sciadv.1700053

DO - 10.1126/sciadv.1700053

M3 - Article

SN - 2375-2548

VL - 3

JO - Science Advances

JF - Science Advances

IS - 6

M1 - e1700053

ER -

Instant tough bonding of hydrogels for soft machines and electronics

Abstract

Fields of science

JKU Focus areas

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