Stretchable, Transparent, Ionic Conductors

Christoph Keplinger; Jeong-Yun Sun; Choon Chiang Foo; Philipp Rothemund; George M. Whitesides; Zhigang Suo

doi:10.1126/science.1240228

Stretchable, Transparent, Ionic Conductors

Science ◽

10.1126/science.1240228 ◽

2013 ◽

Vol 341 (6149) ◽

pp. 984-987 ◽

Cited By ~ 843

Author(s):

Christoph Keplinger ◽

Jeong-Yun Sun ◽

Choon Chiang Foo ◽

Philipp Rothemund ◽

George M. Whitesides ◽

...

Keyword(s):

Electrochemical Reaction ◽

Transparent Conductors ◽

Large Strains ◽

Stretchable Electronics ◽

Ionic Conductors ◽

Sensors And Actuators ◽

Electromechanical Transduction ◽

Highly Stretchable ◽

Electronic Conductors ◽

Lower Sheet Resistance

Existing stretchable, transparent conductors are mostly electronic conductors. They limit the performance of interconnects, sensors, and actuators as components of stretchable electronics and soft machines. We describe a class of devices enabled by ionic conductors that are highly stretchable, fully transparent to light of all colors, and capable of operation at frequencies beyond 10 kilohertz and voltages above 10 kilovolts. We demonstrate a transparent actuator that can generate large strains and a transparent loudspeaker that produces sound over the entire audible range. The electromechanical transduction is achieved without electrochemical reaction. The ionic conductors have higher resistivity than many electronic conductors; however, when large stretchability and high transmittance are required, the ionic conductors have lower sheet resistance than all existing electronic conductors.

Download Full-text

Fatigue-free, superstretchable, transparent, and biocompatible metal electrodes

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1516873112 ◽

2015 ◽

Vol 112 (40) ◽

pp. 12332-12337 ◽

Cited By ~ 56

Author(s):

Chuan Fei Guo ◽

Qihan Liu ◽

Guohui Wang ◽

Yecheng Wang ◽

Zhengzheng Shi ◽

...

Keyword(s):

Flexible Electronics ◽

Indium Tin Oxide ◽

Large Strain ◽

Transparent Conductors ◽

Practical Applications ◽

Highly Stretchable ◽

Implantable Electronics ◽

Electronic Conductors ◽

Strained Materials ◽

Original Configuration

Next-generation flexible electronics require highly stretchable and transparent electrodes. Few electronic conductors are both transparent and stretchable, and even fewer can be cyclically stretched to a large strain without causing fatigue. Fatigue, which is often an issue of strained materials causing failure at low strain levels of cyclic loading, is detrimental to materials under repeated loads in practical applications. Here we show that optimizing topology and/or tuning adhesion of metal nanomeshes can significantly improve stretchability and eliminate strain fatigue. The ligaments in an Au nanomesh on a slippery substrate can locally shift to relax stress upon stretching and return to the original configuration when stress is removed. The Au nanomesh keeps a low sheet resistance and high transparency, comparable to those of strain-free indium tin oxide films, when the nanomesh is stretched to a strain of 300%, or shows no fatigue after 50,000 stretches to a strain up to 150%. Moreover, the Au nanomesh is biocompatible and penetrable to biomacromolecules in fluid. The superstretchable transparent conductors are highly desirable for stretchable photoelectronics, electronic skins, and implantable electronics.

Download Full-text

Introduction

Interfacial Electrochemistry ◽

10.1093/oso/9780195089325.003.0006 ◽

1996 ◽

Author(s):

Wolfgang Schmickler

Keyword(s):

Ionic Conductivities ◽

Electrolyte Solutions ◽

Electrolytic Cell ◽

Ionic Conductor ◽

Electrochemical Kinetics ◽

Ionic Conductors ◽

Working Definition ◽

Long Time ◽

Electrochemical Phenomena ◽

Electronic Conductors

Electrochemistry is an old science: There is good archaeological evidence that an electrolytic cell was used by the Parthans (250 B.C. to 250 A.D.), probably for electroplating, though a proper scientific investigation of electrochemical phenomena did not start before the experiments of Volta and Galvani. The meaning and scope of electrochemical science has varied throughout the ages: For a long time it was little more than a special branch of thermodynamics; later attention turned to electrochemical kinetics. During recent decades, with the application of various surface-sensitive techniques to electrochemical systems, it has become a science of interfaces, and this, we think, is where its future lies. So in this book we use as a working definition: . . . Electrochemistry is the study of structures and processes at the interface between an electronic conductor (the electrode) and an ionic conductor (the electrolyte) or at the interface between two electrolytes. . . This definition requires some explanation. (1) By interface we denote those regions of the two adjoining phases whose properties differ significantly from those of the bulk. These interfacial regions can be quite extended, particularly in those cases where a metal or semiconducting electrode is covered by a thin film. Sometimes the term interphase is used to indicate the spatial extention. (2) It would have been more natural to restrict the definition to the interface between an electronic and an ionic conductor only, and, indeed, this is generally what we mean by the term electrochemical interface. However, the study of the interface between two immiscible electrolyte solutions is so similar that it is natural to include it under the scope of electrochemistry. Metals and semiconductors are common examples of electronic conductors, and under certain circumstances even insulators can be made electronically conducting, for example by photoexcitation. Electrolyte solutions, molten salts, and solid electrolytes are ionic conductors. Some materials have appreciable electronic and ionic conductivities, and depending on the circumstances one or the other or both may be important.

Download Full-text

In-Plane Deformation Mechanics for Highly Stretchable Electronics

Advanced Materials ◽

10.1002/adma.201604989 ◽

2016 ◽

Vol 29 (8) ◽

pp. 1604989 ◽

Cited By ~ 72

Author(s):

Yewang Su ◽

Xuecheng Ping ◽

Ki Jun Yu ◽

Jung Woo Lee ◽

Jonathan A. Fan ◽

...

Keyword(s):

Plane Deformation ◽

Stretchable Electronics ◽

Highly Stretchable ◽

Deformation Mechanics

Download Full-text

Nanoionics and its device applications

10.1093/oxfordhb/9780199533060.013.8 ◽

2017 ◽

Author(s):

T. Hasegawa ◽

K. Terabe ◽

T. Sakamoto ◽

M. Aono

Keyword(s):

Solid Electrolytes ◽

Current Flow ◽

Electrochemical Reaction ◽

Electronic Devices ◽

Low Power Consumption ◽

Ionic Conductors ◽

Conductive Materials ◽

Device Applications ◽

Metal Filament ◽

Atomic Switch

This article discusses nanoionics phenomena and their applications for making new types of electronic devices. It begins with an overview of ionic conductive materials, which are classified into two categories in terms of the charged particles: solid electrolytes in which only ions contribute to the current flow, and mixed electronic and ionic conductors in which bothelectrons and ions contribute to the current flow. It then describes the solid electrochemical reaction that controls metal-filament growth and shrinkage in an atomic switch, along with the fundamentals of an atomic switch. It also considers new types of atomic switches and several applications of atomic switches. Finally, it highlights some novel characteristics of the atomic switch such as small size, low power consumption, non-volatility, and low on-resistance. These characteristics enable us to improve the performance of present-day electronic devices.

Download Full-text

Fast Plasmonic Laser Nanowelding for a Cu-Nanowire Percolation Network for Flexible Transparent Conductors and Stretchable Electronics

Advanced Materials ◽

10.1002/adma.201400474 ◽

2014 ◽

Vol 26 (33) ◽

pp. 5808-5814 ◽

Cited By ~ 299

Author(s):

Seungyong Han ◽

Sukjoon Hong ◽

Jooyeun Ham ◽

Junyeob Yeo ◽

Jinhwan Lee ◽

...

Keyword(s):

Transparent Conductors ◽

Stretchable Electronics ◽

Percolation Network

Download Full-text

Mechanical response of spiral interconnect arrays for highly stretchable electronics

Applied Physics Letters ◽

10.1063/1.5007111 ◽

2017 ◽

Vol 111 (21) ◽

pp. 214102 ◽

Cited By ~ 18

Author(s):

N. Qaiser ◽

S. M. Khan ◽

M. Nour ◽

M. U. Rehman ◽

J. P. Rojas ◽

...

Keyword(s):

Mechanical Response ◽

Stretchable Electronics ◽

Highly Stretchable

Download Full-text

Universal synthesis of conductive liquid network in polymers enabling elastic printed circuit board technology

10.21203/rs.3.rs-1130783/v1 ◽

2021 ◽

Author(s):

Jiheong Kang ◽

Wonbeom Lee ◽

Hyunjun Kim ◽

Inho Kang ◽

Hongjun Park ◽

...

Keyword(s):

Liquid Metal ◽

Acoustic Field ◽

Printed Circuit Board ◽

Circuit Board ◽

System Level ◽

Large Strains ◽

Stretchable Electronics ◽

Electronic Components ◽

Conductive Liquid ◽

Printed Circuit

Abstract Stretchable electronics are considered next-generation electronic devices in a broad range of emerging fields, including soft robotics1,2, biomedical devices3,4, human-machine interfaces5,6, and virtual or augmented reality devices7,8. A stretchable printed circuit board (S-PCB) is a basic conductive framework for the facile assembly of system-level stretchable electronics with various electronic components. Since an S-PCB is responsible for electrical communications between numerous electronic components, the conductive lines in S-PCB should strictly satisfy the following features: (i) metallic conductivity, (ii) constant electrical resistance during dynamic stretching, and (iii) tough interface bonding with various components9. Despite recent significant advances in intrinsically stretchable conductors10,11,12, they cannot simultaneously satisfy the above stringent requirements. Here, we present a new concept of conductive liquid network-based elastic conductors. These conductors are based on unprecedented liquid metal particles assembled network (LMPNet) and an elastomer. The unique assembled network structure and reconfigurable nature of the LMPNet conductor enabled high conductivity, high stretchability, tough adhesion, and imperceptible resistance changes under large strains, which enabled the first elastic-PCB (E-PCB) technology. We synthesized LMPNet through an acoustic field-driven cavitation event in the solid state. When an acoustic field is applied, liquid metal nanoparticles (LMPnano) are remarkably generated from original LMPs and assemble into a highly conductive particle network (LMPNet). Finally, we demonstrated a multi-layered E-PCB, in which various electronic components were integrated with tough adhesion to form a highly stretchable health monitoring system. Since our synthesis of LMPNet is universal, we could synthesize LMPNet in various polymers, including hydrogel, self-healing elastomer and photoresist and add new functions to LMPNet.

Download Full-text

Stretchable distributed fiber-optic sensors

Science ◽

10.1126/science.aba5504 ◽

2020 ◽

Vol 370 (6518) ◽

pp. 848-852

Author(s):

Hedan Bai ◽

Shuo Li ◽

Jose Barreiros ◽

Yaqi Tu ◽

Clifford R. Pollock ◽

...

Keyword(s):

Total Internal Reflection ◽

Fiber Optic ◽

Fiber Optic Sensor ◽

Large Strains ◽

Stretchable Electronics ◽

Vibration Acceleration ◽

Frustrated Total Internal Reflection ◽

Optic Sensor ◽

Distributed Fiber Optic Sensor ◽

Single Sensor

Silica-based distributed fiber-optic sensor (DFOS) systems have been a powerful tool for sensing strain, pressure, vibration, acceleration, temperature, and humidity in inextensible structures. DFOS systems, however, are incompatible with the large strains associated with soft robotics and stretchable electronics. We develop a sensor composed of parallel assemblies of elastomeric lightguides that incorporate continuum or discrete chromatic patterns. By exploiting a combination of frustrated total internal reflection and absorption, stretchable DFOSs can distinguish and measure the locations, magnitudes, and modes (stretch, bend, or press) of mechanical deformation. We further demonstrate multilocation decoupling and multimodal deformation decoupling through a stretchable DFOS–integrated wireless glove that can reconfigure all types of finger joint movements and external presses simultaneously, with only a single sensor in real time.

Download Full-text

Stretchable, Rehealable, Recyclable, and Reconfigurable Integrated Strain Sensor for Joint Motion and Respiration Monitoring

Research ◽

10.34133/2021/9846036 ◽

2021 ◽

Vol 2021 ◽

pp. 1-14

Author(s):

Chuanqian Shi ◽

Zhanan Zou ◽

Zepeng Lei ◽

Pengcheng Zhu ◽

Guohua Nie ◽

...

Keyword(s):

Stretchable Electronics ◽

Joint Motion ◽

Wearable Electronics ◽

Strain Sensing ◽

Eutectic Liquid ◽

Respiration Monitoring ◽

Sensing System ◽

Liquid Metal Alloy ◽

Highly Stretchable ◽

Different Parts

Cutting-edge technologies of stretchable, skin-mountable, and wearable electronics have attracted tremendous attention recently due to their very wide applications and promising performances. One direction of particular interest is to investigate novel properties in stretchable electronics by exploring multifunctional materials. Here, we report an integrated strain sensing system that is highly stretchable, rehealable, fully recyclable, and reconfigurable. This system consists of dynamic covalent thermoset polyimine as the moldable substrate and encapsulation, eutectic liquid metal alloy as the strain sensing unit and interconnects, and off-the-shelf chip components for measuring and magnifying functions. The device can be attached on different parts of the human body for accurately monitoring joint motion and respiration. Such a strain sensing system provides a reliable, economical, and ecofriendly solution to wearable technologies, with wide applications in health care, prosthetics, robotics, and biomedical devices.

Download Full-text