Nature Communications (Apr 2024)

Full integration of highly stretchable inorganic transistors and circuits within molecular-tailored elastic substrates on a large scale

  • Seung-Han Kang,
  • Jeong-Wan Jo,
  • Jong Min Lee,
  • Sanghee Moon,
  • Seung Bum Shin,
  • Su Bin Choi,
  • Donghwan Byeon,
  • Jaehyun Kim,
  • Myung-Gil Kim,
  • Yong-Hoon Kim,
  • Jong-Woong Kim,
  • Sung Kyu Park

DOI
https://doi.org/10.1038/s41467-024-47184-w
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 12

Abstract

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Abstract The emergence of high-form-factor electronics has led to a demand for high-density integration of inorganic thin-film devices and circuits with full stretchability. However, the intrinsic stiffness and brittleness of inorganic materials have impeded their utilization in free-form electronics. Here, we demonstrate highly integrated strain-insensitive stretchable metal-oxide transistors and circuitry (442 transistors/cm2) via a photolithography-based bottom-up approach, where transistors with fluidic liquid metal interconnection are embedded in large-area molecular-tailored heterogeneous elastic substrates (5 × 5 cm2). Amorphous indium-gallium-zinc-oxide transistor arrays (7 × 7), various logic gates, and ring-oscillator circuits exhibited strain-resilient properties with performance variation less than 20% when stretched up to 50% and 30% strain (10,000 cycles) for unit transistor and circuits, respectively. The transistors operate with an average mobility of 12.7 ( ± 1.7) cm2 V−1s−1, on/off current ratio of > 107, and the inverter, NAND, NOR circuits operate quite logically. Moreover, a ring oscillator comprising 14 cross-wired transistors validated the cascading of the multiple stages and device uniformity, indicating an oscillation frequency of ~70 kHz.