Title :
Low-Temperature Fabricated TFTs on Polysilicon Stripes
Author :
Brunets, Ihor ; Holleman, Jisk ; Kovalgin, Alexey Y. ; Boogaard, Arjen ; Schmitz, Jurriaan
Author_Institution :
Dept. of Semicond. Components, Univ. of Twente, Enschede, Netherlands
Abstract :
This paper presents a novel approach to make high-performance CMOS at low temperatures. Fully functional devices are manufactured using back-end compatible substrate temperatures after the deposition of the amorphous-silicon starting material. The amorphous silicon is pretextured to control the location of grain boundaries. Green-laser annealing is employed for crystallization and dopant activation. A high activation level of As and B impurities is obtained. The main grain boundaries are found at predictable positions, allowing transistor definition away from these boundaries. The realized thin-film transistors (TFTs) exhibit high field-effect carrier mobilities of 405 cm2/Vmiddots (NMOS) and 128 cm2/Vmiddots (PMOS). CMOS inverters and fully functional 51-stage ring oscillators were fabricated in this process and characterized. The process can be employed for large-area TFT electronics as well as a functional stack layer in 3-D integration.
Keywords :
CMOS integrated circuits; amorphous semiconductors; carrier mobility; cryogenic electronics; grain boundaries; laser beam annealing; thin film transistors; CMOS inverters; NMOS; PMOS; Si; amorphous silicon; carrier mobilities; crystallization; dopant activation; grain boundaries; green laser annealing; low temperature electronics; polysilicon stripes; ring oscillators; substrate temperatures; thin film transistors; Amorphous silicon; Annealing; Crystalline materials; Crystallization; Grain boundaries; Impurities; Manufacturing; Substrates; Temperature; Thin film transistors; 3-D integration; Above integrated circuit (IC); grain boundary; laser annealing; polycrystalline silicon; thin-film transistor (TFT);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2009.2023021
