Title :
A self-aligned, electrically separable double-gate MOS transistor technology for dynamic threshold voltage application
Author :
Zhang, Shengdong ; Lin, Xinnan ; Huang, Ru ; Han, Ruqi ; Chan, Mansun
Author_Institution :
Inst. of Microelectron., Peking Univ., Beijing, China
Abstract :
In this brief, a self-aligned electrically separable double-gate (SA ESDG) MOS transistor technology is proposed and demonstrated. The SA ESDG structure is implemented by defining a dummy top gate that is self-aligned to the bottom gate and then later replacing the dummy using a real top gate. The proposed process is applied to the single-grain Si film formed by recrystallizing a low-pressure chemical vapor deposition a-Si with a metal induced unilateral crystallization technique and enhancing the grain sizes in a subsequent high temperature annealing step. The ideal device structure resulting from the process is verified by scanning electron microscope imaging. The good current-voltage characteristics and the noticeable dynamic threshold voltage effects are also observed in the implemented SA ESDG device.
Keywords :
MOSFET; chemical vapour deposition; grain size; recrystallisation annealing; scanning electron microscopy; silicon-on-insulator; SA ESDG structure; current-voltage characteristics; double-gate SOI MOSFET; dummy top gate; dynamic threshold voltage application; grain size enhancement; high temperature annealing; low-pressure chemical vapor deposition; metal induced unilateral crystallization technique; real top gate; scanning electron microscope imaging; self-aligned electrically separable double-gate MOS transistor technology; self-aligned structure; single-grain Si film; Annealing; Chemical technology; Chemical vapor deposition; Crystallization; Electrons; Grain size; MOSFETs; Semiconductor films; Temperature; Threshold voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2003.818598
