Flash-Induced Stretchable Cu Conductor via Multiscale-Interfacial Couplings

Jung Hwan Park; Jeongmin Seo; Cheolgyu Kim; Daniel J. Joe; Han Eol Lee; Tae Hong Im; Jae Young Seok; Chang Kyu Jeong; Boo Soo Ma; Hyung Kun Park; Taek Soo Kim; Keon Jae Lee

doi:10.1002/advs.201801146

Flash-Induced Stretchable Cu Conductor via Multiscale-Interfacial Couplings

Jung Hwan Park
, Jeongmin Seo
, Cheolgyu Kim
, Daniel J. Joe
, Han Eol Lee
, Tae Hong Im
, Jae Young Seok
, Chang Kyu Jeong
, Boo Soo Ma
, Hyung Kun Park
, Taek Soo Kim
, Keon Jae Lee^*

^*Corresponding author for this work

Electronic Materials Engineering

Korea Advanced Institute of Science and Technology

Research output: Contribution to journal › Journal article › peer-review

46 Scopus citations

Abstract

Herein, a novel stretchable Cu conductor with excellent conductivity and stretchability is reported via the flash-induced multiscale tuning of Cu and an elastomer interface. Microscale randomly wrinkled Cu (amplitude of ≈5 µm and wavelength of ≈45 µm) is formed on a polymer substrate through a single pulse of a millisecond flash light, enabling the elongation of Cu to exceed 20% regardless of the stretching direction. The nanoscale interlocked interface between the Cu nanoparticles (NPs) and the elastomer increases the adhesion force of Cu, which contributes to a significant improvement of the Cu stability and stretchability under harsh yielding stress. Simultaneously, the flash-induced photoreduction of CuO NPs and subsequent Cu NP welding lead to outstanding conductivity (≈37 kS cm⁻¹) of the buckled elastic electrode. The 3D structure of randomly wrinkled Cu is modeled by finite element analysis simulations to show that the flash-activated stretchable Cu conductors can endure strain over 20% in all directions. Finally, the wrinkled Cu is utilized for wireless near-field communication on the skin of human wrist.

Original language	English
Article number	1801146
Journal	Advanced Science
Volume	5
Issue number	11
DOIs	https://doi.org/10.1002/advs.201801146
State	Published - 2018.11

Keywords

flash–material interactions
interlocking
stretchable conductors
wireless communication
wrinkling

Quacquarelli Symonds(QS) Subject Topics

Materials Science
Medicine
Engineering - Chemical
Physics & Astronomy
Biological Sciences

Access to Document

10.1002/advs.201801146

Cite this

@article{fa0e228806524742b6a30ce6543841a9,

title = "Flash-Induced Stretchable Cu Conductor via Multiscale-Interfacial Couplings",

abstract = "Herein, a novel stretchable Cu conductor with excellent conductivity and stretchability is reported via the flash-induced multiscale tuning of Cu and an elastomer interface. Microscale randomly wrinkled Cu (amplitude of ≈5 µm and wavelength of ≈45 µm) is formed on a polymer substrate through a single pulse of a millisecond flash light, enabling the elongation of Cu to exceed 20\% regardless of the stretching direction. The nanoscale interlocked interface between the Cu nanoparticles (NPs) and the elastomer increases the adhesion force of Cu, which contributes to a significant improvement of the Cu stability and stretchability under harsh yielding stress. Simultaneously, the flash-induced photoreduction of CuO NPs and subsequent Cu NP welding lead to outstanding conductivity (≈37 kS cm−1) of the buckled elastic electrode. The 3D structure of randomly wrinkled Cu is modeled by finite element analysis simulations to show that the flash-activated stretchable Cu conductors can endure strain over 20\% in all directions. Finally, the wrinkled Cu is utilized for wireless near-field communication on the skin of human wrist.",

keywords = "flash–material interactions, interlocking, stretchable conductors, wireless communication, wrinkling",

author = "Park, \{Jung Hwan\} and Jeongmin Seo and Cheolgyu Kim and Joe, \{Daniel J.\} and Lee, \{Han Eol\} and Im, \{Tae Hong\} and Seok, \{Jae Young\} and Jeong, \{Chang Kyu\} and Ma, \{Boo Soo\} and Park, \{Hyung Kun\} and Kim, \{Taek Soo\} and Lee, \{Keon Jae\}",

note = "Publisher Copyright: {\textcopyright} 2018 The Authors. Published by WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2018",

month = nov,

doi = "10.1002/advs.201801146",

language = "English",

volume = "5",

journal = "Advanced Science",

issn = "2198-3844",

number = "11",

}

TY - JOUR

T1 - Flash-Induced Stretchable Cu Conductor via Multiscale-Interfacial Couplings

AU - Park, Jung Hwan

AU - Seo, Jeongmin

AU - Kim, Cheolgyu

AU - Joe, Daniel J.

AU - Lee, Han Eol

AU - Im, Tae Hong

AU - Seok, Jae Young

AU - Jeong, Chang Kyu

AU - Ma, Boo Soo

AU - Park, Hyung Kun

AU - Kim, Taek Soo

AU - Lee, Keon Jae

PY - 2018/11

Y1 - 2018/11

N2 - Herein, a novel stretchable Cu conductor with excellent conductivity and stretchability is reported via the flash-induced multiscale tuning of Cu and an elastomer interface. Microscale randomly wrinkled Cu (amplitude of ≈5 µm and wavelength of ≈45 µm) is formed on a polymer substrate through a single pulse of a millisecond flash light, enabling the elongation of Cu to exceed 20% regardless of the stretching direction. The nanoscale interlocked interface between the Cu nanoparticles (NPs) and the elastomer increases the adhesion force of Cu, which contributes to a significant improvement of the Cu stability and stretchability under harsh yielding stress. Simultaneously, the flash-induced photoreduction of CuO NPs and subsequent Cu NP welding lead to outstanding conductivity (≈37 kS cm−1) of the buckled elastic electrode. The 3D structure of randomly wrinkled Cu is modeled by finite element analysis simulations to show that the flash-activated stretchable Cu conductors can endure strain over 20% in all directions. Finally, the wrinkled Cu is utilized for wireless near-field communication on the skin of human wrist.

AB - Herein, a novel stretchable Cu conductor with excellent conductivity and stretchability is reported via the flash-induced multiscale tuning of Cu and an elastomer interface. Microscale randomly wrinkled Cu (amplitude of ≈5 µm and wavelength of ≈45 µm) is formed on a polymer substrate through a single pulse of a millisecond flash light, enabling the elongation of Cu to exceed 20% regardless of the stretching direction. The nanoscale interlocked interface between the Cu nanoparticles (NPs) and the elastomer increases the adhesion force of Cu, which contributes to a significant improvement of the Cu stability and stretchability under harsh yielding stress. Simultaneously, the flash-induced photoreduction of CuO NPs and subsequent Cu NP welding lead to outstanding conductivity (≈37 kS cm−1) of the buckled elastic electrode. The 3D structure of randomly wrinkled Cu is modeled by finite element analysis simulations to show that the flash-activated stretchable Cu conductors can endure strain over 20% in all directions. Finally, the wrinkled Cu is utilized for wireless near-field communication on the skin of human wrist.

KW - flash–material interactions

KW - interlocking

KW - stretchable conductors

KW - wireless communication

KW - wrinkling

UR - https://www.scopus.com/pages/publications/85054500744

U2 - 10.1002/advs.201801146

DO - 10.1002/advs.201801146

M3 - Journal article

AN - SCOPUS:85054500744

SN - 2198-3844

VL - 5

JO - Advanced Science

JF - Advanced Science

IS - 11

M1 - 1801146

ER -

Flash-Induced Stretchable Cu Conductor via Multiscale-Interfacial Couplings

Abstract

Keywords

Quacquarelli Symonds(QS) Subject Topics

Access to Document

Other files and links

Fingerprint

Cite this