Abstract Conventional silicon-based tunneling field-effect transistors (TFETs) face several issues, including limited ON current, ambipolar conduction, and suboptimal RF performance. This simulation-based study presents a detailed design and optimization approach for a high-performance heterostructure nanowire tunneling FET (NW-TFET). Starting from a fabricated baseline NW-TFET structure, we modify the design through a series of optimization phases to improve both DC and radio-frequency (RF) characteristics. The proposed design features a heterojunction structure in which the source region is composed of Si1 − xGex to enhance the tunneling probability, thereby increasing the ON current. The design also includes the integration of a 15 nm HfO2 pocket, careful tuning of gate-source alignment, and optimization of the x-composition in the source. Extensive simulations show significant improvements in ON current (ION), ON/OFF current ratio, subthreshold swing, and cutoff frequency (\ (\: fₓ) \) compared to the initial configuration, with x = 0. 75, 0. 5 nm pocket underlap, 50 nm gate length, \ (\: 60\: nm\: \) channel length and work function of 4. 3 eV. The optimized device achieves an ON/OFF ratio of 4. 79×106, a subthreshold swing (SS) of 64. 5 mV/decade, threshold voltage (\ (\: Vₓ) \: \) of 0. 253 V and a maximum cutoff frequency of 355 GHz, while keeping ambipolar current low. These findings highlight the potential of the proposed NW-TFET architecture for low-power, high-speed applications.
Labib et al. (Tue,) studied this question.