Nature Communications (Apr 2024)

Integrated 2D multi-fin field-effect transistors

  • Mengshi Yu,
  • Congwei Tan,
  • Yuling Yin,
  • Junchuan Tang,
  • Xiaoyin Gao,
  • Hongtao Liu,
  • Feng Ding,
  • Hailin Peng

DOI
https://doi.org/10.1038/s41467-024-47974-2
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Vertical semiconducting fins integrated with high-κ oxide dielectrics have been at the centre of the key device architecture that has promoted advanced transistor scaling during the last decades. Single-fin channels based on two-dimensional (2D) semiconductors are expected to offer unique advantages in achieving sub-1 nm fin-width and atomically flat interfaces, resulting in superior performance and potentially high-density integration. However, multi-fin structures integrated with high-κ dielectrics are commonly required to achieve higher electrical performance and integration density. Here we report a ledge-guided epitaxy strategy for growing high-density, mono-oriented 2D Bi2O2Se fin arrays that can be used to fabricate integrated 2D multi-fin field-effect transistors. Aligned substrate steps enabled precise control of both nucleation sites and orientation of 2D fin arrays. Multi-channel 2D fin field-effect transistors based on epitaxially integrated 2D Bi2O2Se/Bi2SeO5 fin-oxide heterostructures were fabricated, exhibiting an on/off current ratio greater than 106, high on-state current, low off-state current, and high durability. 2D multi-fin channel arrays integrated with high-κ oxide dielectrics offer a strategy to improve the device performance and integration density in ultrascaled 2D electronics.