Flash-welded ultraflat silver nanowire network for flexible organic light-emitting diode and triboelectric tactile sensor

Hee Seung Wang,Han Eol Lee,Seongwook Min,Sang Hyun Park,Sang Hyun Sung,Chang Kyu Jeong,Tae Hong Im,Jung Hwan Park,Young Bin Kim,Keon Jae Lee

doi:10.1063/5.0051431

Abstract

Transparent flexible electrodes of metallic nanowire have been spotlighted to develop form factor free electronics for human-machine interfaces. However, state-of-the-art nanowire electrodes have been restricted for flexible application due to multi-stacked morphology with large protrusion and high surface roughness, which generate critical leakage current and device malfunction. Light-material interactions using board-wavelength flash lamps can be a solution for outstanding electrical and morphological properties by inducing a plasmonic welding of flexible metal nanowire. Herein, we propose flash-welded ultraflat electrode networks enabled by nanowire embedding to reduce the protrusion and surface roughness. The nanowire embedded in elastomer presented an ultra-smooth surface of Rq ~ 1.4 nm that prevents leakage current in ultrathin flexible electronics. The excellent electrical properties of ultraflat composite electrode were realized by xenon flash-induced junction welding of metal nanowire. The mechanical stability of flash-welded electrode was confirmed by sheet resistance value under cyclic bending test. Finally, ultraflat silver nanowire networks were utilized in practical application of a leakage current-free flexible optoelectronic device and a triboelectric tactile sensor.

Highlights

Light–material interactions using monochromatic lasers and broad-wavelength flash lamps have been spotlighted to improve the electrical properties of flexible metal NW conductors.[33–36] Conventionally, plasmonic metal NW welding was conducted via laser irradiation methods due to its significant capability to precisely adjust processing parameters for heat transfer
We report ultraflat AgNW networks with excellent electrical conductivity enabled by AgNW embedding and subsequent flash-induced NW welding
Water-soluble PEDOT:PSS was successfully employed as a sacrificial layer to delaminate the embedded AgNW composite from the mother glass substrates, enabling free-standing AgNW/Norland 73 (NOA) transparent flexible electrodes (TFEs) with significantly reduced NW protrusion and surface roughness

Summary

Introduction

Light–material interactions using monochromatic lasers and broad-wavelength flash lamps have been spotlighted to improve the electrical properties of flexible metal NW conductors.[33–36] Conventionally, plasmonic metal NW welding was conducted via laser irradiation methods due to its significant capability to precisely adjust processing parameters for heat transfer.

Results

Conclusion