A monolithic fabrication platform for intrinsically stretchable polymer transistors and complementary circuits
Abstract
Soft, stretchable organic field-effect transistors (OFETs) can provide powerful on-skin signal conditioning, but current fabrication methods are often material-specific: each new polymer semiconductor (PSC) requires a tailored process. The challenge is even greater for complementary OFET circuits, where two PSCs must be patterned sequentially, which often leads to device degradation. Here, we introduce a universal, monolithic photolithography process that enables high-yield, high-resolution stretchable complementary OFETs and circuits. This approach is enabled by a process-design framework that includes (i) a direct, photopatternable, solvent-resistant, crosslinked dielectric/semiconductor interface, (ii) broadly applicable crosslinked PSC blends that preserve high mobility, and (iii) a patterning strategy that provides simultaneous etch masking and encapsulation. Using this platform, we achieve record integration density for stretchable OTFTs (55,000 cm^-2), channel lengths down to 2 um, and low-voltage operation at 5 V. We demonstrate photopatterning across multiple PSC types and realize complementary circuits, including 3 kHz stretchable ring oscillators, the first to exceed 1 kHz and representing more than a 60-fold increase in stage switching speed over the state of the art. Finally, we demonstrate the first stretchable complementary OTFT neuron circuit, where the output frequency is modulated by the input current to mimic neuronal signal processing. This scalable approach can be readily extended to diverse high-performance stretchable materials, accelerating the development and manufacturing of skin-like electronics.
Keywords
Cite
@article{arxiv.2601.10975,
title = {A monolithic fabrication platform for intrinsically stretchable polymer transistors and complementary circuits},
author = {Yujia Yuan and Chuanzhen Zhao and Margherita Ronchini and Yuya Nishio and Donglai Zhong and Can Wu and Hyukmin Kweon and Zehao Sun and Rachael K. Mow and Yuran Shi and Lukas Michalek and Haotian Wu and Qianhe Liu and Weichen Wang and Yating Yao and Zelong Yin and Junyi Zhao and Zihan He and Ke Chen and Ruiheng Wu and Jiuyun Shi and Jian Pei and Zhenan Bao},
journal= {arXiv preprint arXiv:2601.10975},
year = {2026}
}
Comments
Submitted to Nature Electronics by December 2025