Title :
Optimization of post N2 treatment & USG cap layer to improve tungsten peeling defects for deep sub-micron device yield improvement
Author :
Cheng, Y.L. ; Wang, Y.L. ; Wu, S.A. ; Wang, H.L. ; Wang, J.K.
Author_Institution :
Taiwan Semicond. Manuf. Co. Ltd., Hsin-Chu, Taiwan
Abstract :
Integration issue of W-plug peeling from fluorinated silica glass (FSG) in deep sub-micron IMD application was investigated in this study. Tungsten would peel off immediately during post CMP N2 treatment in-situ running with USG cap layer deposition after W-plug deposition. Separating or optimizing post-CMP N2 treatment and cap layer would solve this peeling issue. The key points of peeling were the bias power of N2 treatment and initial USG cap temperature in the HDP-CVD chamber. TOF-SIMS analysis revealed that higher bias power and longer treatment time lead to more fluorine distribution on the USG cap layer surface, which may cause non-Si-F bonding fluorine to react with subsequent Ti/TiN/W metal layer. FTIR spectra also showed that low bias power, adding an extra cooling step before substantial in-situ cap layer deposition or ex-situ cap would increase fluorine stability in FSG/USG interface.
Keywords :
Fourier transform spectra; infrared spectra; integrated circuit interconnections; integrated circuit yield; nitridation; optimisation; secondary ion mass spectra; surface treatment; time of flight spectra; tungsten; FTIR spectra; IC interconnection; N2; TOF-SIMS analysis; Ti-TiN-W; USG cap layer; W-plug peeling; deep sub-micron IMD application; deep submicron device yield improvement; fluorinated silica glass; peeling defects improvement; post N2 treatment optimization; Annealing; Argon; Bonding; Furnaces; Glass; Plasma stability; Plasma temperature; Silicon compounds; Surface treatment; Tungsten;
Conference_Titel :
Semiconductor Manufacturing, 2000. Proceedings of ISSM 2000. The Ninth International Symposium on
Print_ISBN :
0-7803-7392-8
DOI :
10.1109/ISSM.2000.993707
