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Logic Gates Based on 3D Vertical Junctionless Gate-All-Around Transistors with Reliable Multilevel Contact

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This study presents a novel dual-input logic gate using 3D vertical gate-all-around (V-GAA) transistors. The lift-off-free fabrication method enhances performance and opens new avenues for 3D integrated circuits.

Keywords:
3D devicelogic gatesnanoelectronicsnanowirescaled gate-all-aroundvertical transport transistor

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Area of Science:

  • Semiconductor device physics
  • Advanced transistor technology
  • Nanoscale fabrication

Background:

  • Vertical gate-all-around (V-GAA) transistors are crucial for future semiconductor technology but face fabrication challenges.
  • Existing methods for fabricating V-GAA devices often involve complex processes like lift-off, impacting yield and performance.

Purpose of the Study:

  • To introduce a novel dual-input logic gate circuit using 3D vertical transistors.
  • To demonstrate a lift-off-free fabrication technique for nanoscale sub-20-nm V-GAA devices.
  • To explore new design possibilities in advanced 3D logic circuitry.

Main Methods:

  • Development of a novel contact and metallic line patterning technique without a conventional lift-off process.
  • Implementation of a two-step oxidation process for field oxide and gate oxide formation on nanowires (NWs).
  • Fabrication of V-GAA-NW transistors using the lift-off-free approach.

Main Results:

  • V-GAA-NW transistors fabricated with the lift-off-free method show improved yield and reduced access resistance.
  • Enhanced drive current and maintained immunity against short-channel effects were observed.
  • Successful demonstration of elementary two-input logic gates within a single cell using VNW transistors.

Conclusions:

  • The novel lift-off-free fabrication technique is effective for V-GAA-NW transistors.
  • The developed approach offers improved device performance and fabrication efficiency.
  • This work presents new possibilities for advanced logic circuitry design and routing in 3D integrated systems.