Title :
Self-passivated copper gates for amorphous silicon thin-film transistors
Author :
Sirringhaus, H. ; Theiss, S.D. ; Kahn, A. ; Wagner, S.
Author_Institution :
Dept. of Electr. Eng., Princeton Univ., NJ, USA
Abstract :
A solution to the amorphous silicon transistor gate metallization problem in active matrix liquid crystal displays (AMLCD´s) is demonstrated, in the form of a self-passivated copper (Cu) process. Cu is passivated by a self-aligned chromium (Cr) oxide encapsulation formed by surface segregation of Cr in dilute Cu-10-30 at.%Cr alloys at 400/spl deg/C, solving the problems of chemical reactivity during the plasma deposition, diffusion, poor adhesion to the substrate, and oxidation. The performance of self-passivated Cu bottom-gate thin-film transistors (TFT´s) and their stability during thermal bias stress testing is comparable to that of Cr-gate reference TFT´s. The gate line resistivity (including encapsulation) is 4.5 μ/spl Omega//spl middot/cm at present.
Keywords :
amorphous semiconductors; copper; elemental semiconductors; encapsulation; passivation; plasma CVD coatings; semiconductor device metallisation; silicon; thin film transistors; 400 C; Cu-Cr; Si; active matrix liquid crystal display; adhesion; amorphous silicon thin-film transistor; chemical reactivity; chromium oxide encapsulation; diffusion; dilute Cu-Cr alloy; gate line resistivity; metallization; oxidation; plasma deposition; self-passivated copper gate; surface segregation; thermal bias stress testing; Active matrix liquid crystal displays; Amorphous silicon; Chemicals; Chromium alloys; Copper alloys; Encapsulation; Metallization; Semiconductor thin films; Thermal stresses; Thin film transistors;
Journal_Title :
Electron Device Letters, IEEE
