Performance evaluation of novel mid-insulation gate junctionless transistors at the device and circuit level
Keywords:
Mid-insulation gate, Junctionless transistor, Surface potential, Drain current, TransconductanceAbstract
This work proposes a novel gate-engineered Mid-Insulation Gate Junctionless Transistor (MiG-JLT) and presents a comparative per
This work proposes a novel gate-engineered Mid-Insulation Gate Junctionless Transistor (MiG-JLT) and presents a comparative performance evaluation against the conventional Symmetric Double Gate Junctionless Transistor (SDG-JLT). Under identical physical parameters, the proposed MiG-JLT demonstrates a nearly 35% enhancement in ON-state current, achieving an ON current of approximately 2.5 10–5 A and an ION/IOFF ratio of about 2.5 108. For a silicon body thickness of 10 nm, the device exhibits a peak transconductance of ~7 10–5 S, and a drain conductance of ~1.3 10–4 S at low drain bias, confirming its improved analog performance. The effects of doping concentration, surface potential distribution, and channel width are systematically analyzed. Circuit-level inverter analysis further demonstrates enhanced transfer and switching characteristics. Overall, the proposed MiG-JLT shows strong potential for high-performance nanoscale and SPICE-compatible device applications.
formance evaluation against the conventional Symmetric Double Gate Junctionless Transistor (SDG-JLT). Under identical physical parameters, the proposed MiG-JLT demonstrates a nearly 35% enhancement in ON-state current, achieving an ON current of approximately 2.5 10–5 A and an ION/IOFF ratio of about 2.5 108. For a silicon body thickness of 10 nm, the device exhibits a peak transconductance of ~7 10–5 S, and a drain conductance of ~1.3 10–4 S at low drain bias, confirming its improved analog performance. The effects of doping concentration, surface potential distribution, and channel width are systematically analyzed. Circuit-level inverter analysis further demonstrates enhanced transfer and switching characteristics. Overall, the proposed MiG-JLT shows strong potential for high-performance nanoscale and SPICE-compatible device applications.
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Copyright (c) 2026 International Journal of Nanoelectronics and Materials (IJNeaM)
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