Photothermal Lithography for Realizing a Stretchable Multilayer Electronic Circuit Using a Laser

Photolithography is a well-established fabrication method for realizing multilayer electronic circuits. However, it is challenging to adopt photolithography to fabricate intrinsically stretchable multilayer electronic circuits fully composed of an elastomeric matrix, due to the opacity of thick stre...

Full description

Saved in:
Bibliographic Details
Published in:ACS nano 2023-11, Vol.17 (21), p.21443-21454
Main Authors: Song, Sangmin, Hong, Hyejun, Kim, Kyung Yeun, Kim, Kyun Kyu, Kim, Jaewoo, Won, Daeyeon, Yun, Soyoung, Choi, Joonhwa, Ryu, Young-In, Lee, Kyungwoo, Park, Jaeho, Kang, Joohyuk, Bang, Junhyuk, Seo, Hyunseon, Kim, Yu-Chan, Lee, Daeho, Lee, Haechang, Lee, Jinwoo, Hwang, Suk-Won, Ko, Seung Hwan, Jeon, Hojeong, Lee, Wonryung
Format: Article
Language:English
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Photolithography is a well-established fabrication method for realizing multilayer electronic circuits. However, it is challenging to adopt photolithography to fabricate intrinsically stretchable multilayer electronic circuits fully composed of an elastomeric matrix, due to the opacity of thick stretchable nanocomposite conductors. Here, we present photothermal lithography that can pattern elastomeric conductors and via holes using pulsed lasers. The photothermal-patterned stretchable nanocomposite conductor exhibits 3 times higher conductivity (5940 S cm–1) and 5 orders of magnitude lower resistance change (R/R 0 = 40) under a 30% strained 5000th cyclic stretch, compared to those of a screen-printed conductor, based on the percolation network formed by spatial heating of the laser. In addition, a 50 μm sized stretchable via holes can be patterned on the passivation without material ablation and electrical degradation of the bottom conductor. By repeatedly patterning the conductor and via holes, highly conductive and durable multilayer circuits can be stacked with layer-by-layer material integration. Finally, a stretchable wireless pressure sensor and passive matrix LED array are demonstrated, thus showing the potential for a stretchable multilayer electronic circuit with durability, high density, and multifunctionality.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.3c06207