Highly Stretchable, High‐Mobility, Free‐Standing All‐Organic Transistors Modulated by Solid‐State Elastomer Electrolytes
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Title
Highly Stretchable, High‐Mobility, Free‐Standing All‐Organic Transistors Modulated by Solid‐State Elastomer Electrolytes
Authors
Keywords
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Journal
ADVANCED FUNCTIONAL MATERIALS
Volume -, Issue -, Pages 1808909
Publisher
Wiley
Online
2019-02-06
DOI
10.1002/adfm.201808909
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- (2011) Darren J. Lipomi et al. CHEMISTRY OF MATERIALS
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- Stretchable Graphene Transistors with Printed Dielectrics and Gate Electrodes
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- Elastomeric Conductive Composites Based on Carbon Nanotube Forests
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