Title :
Modeling of grain growth mechanism by nickel silicide reactive grain boundary effect in metal-induced-lateral-crystallization
Author :
Cheng, C.F. ; Poon, Vincent M C ; Kok, C.W. ; Chan, Mansun
Author_Institution :
Dept. of Electr. & Electron. Eng., Hong Kong Univ. of Sci. & Technol., China
fDate :
6/1/2003 12:00:00 AM
Abstract :
The growth mechanism of metal-induced-lateral-crystallization (MILC) was studied and modeled. Based on the time evolution of the metal impurity in the amorphous silicon film being crystallized, a model has been developed to predict the growth rate and the final metal distribution in the crystallized polysilicon. The model prediction has been compared with experimental results and high prediction accuracy is demonstrated. Using the model, the effects of annealing temperature, annealing time and initial metal concentration on the final grain size and metal impurity distribution can be analyzed. As a result, the model can be used to optimize the grain growth conditions for fabricating high performance thin-film-transistors on the recrystallized polysilicon film.
Keywords :
annealing; crystallisation; elemental semiconductors; grain boundaries; grain growth; grain size; impurities; nickel compounds; semiconductor process modelling; semiconductor thin films; silicon; thin film transistors; MILC process; NiSi reactive grain boundary effect; NiSi-Si; amorphous Si film; annealing temperature; annealing time; crystallized polysilicon film; grain growth conditions optimization; grain growth mechanism modeling; grain size; high performance TFTs; initial metal concentration; metal impurity distribution; metal-induced-lateral-crystallization; model prediction; thin-film-transistors; Amorphous silicon; Annealing; Crystallization; Grain boundaries; Grain size; Impurities; Nickel; Predictive models; Semiconductor films; Silicides;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2003.813521
