This study combines direct measurements of strain, electrical mobility measurements, and a rigorous modeling approach to provide insights about strain-induced mobility enhancement in FinFETs and guidelines for device optimization. Good agreement between simulated and measured mobility is obtained using strain components measured directly at device level by a novel holographic technique. A large vertical compressive strain is observed in metal gate FinFETs, and the simulations show that this helps recover the electron mobility disadvantage of the (110) FinFET lateral interfaces with respect to (100) interfaces, with no degradation of the hole mobility. The model is then used to systematically explore the impact of stress components in the fin width, height, and length directions on the mobility of both n- and p-type FinFETs and to identify optimal stress configurations. Finally, self-consistent Monte Carlo simulations are used to investigate how the most favorable stress configurations can improve the on current of nanoscale MOSFETs.
Investigation of Strain Engineering in FinFETs Comprising Experimental Analysis and Numerical Simulations / Conzatti, Francesco; Serra, Nicola; Esseni, David; De Michielis, M.; Paussa, Alan; Palestri, Pierpaolo; Selmi, Luca; Thomas, S. M.; Whall, T. E.; Leadley, D.; Parker, E. H. C.; Witters, L.; Hytch, M. J.; Snoeck, E.; Wang, T. J.; Lee, W. C.; Doornbos, G.; Vellianitis, G.; van Dal, M. J. H.; Lander, R. J. P.. - In: IEEE TRANSACTIONS ON ELECTRON DEVICES. - ISSN 0018-9383. - 58:(2011), pp. 1583-1593. [10.1109/TED.2011.2119320]
Investigation of Strain Engineering in FinFETs Comprising Experimental Analysis and Numerical Simulations
PALESTRI, Pierpaolo;SELMI, Luca;
2011
Abstract
This study combines direct measurements of strain, electrical mobility measurements, and a rigorous modeling approach to provide insights about strain-induced mobility enhancement in FinFETs and guidelines for device optimization. Good agreement between simulated and measured mobility is obtained using strain components measured directly at device level by a novel holographic technique. A large vertical compressive strain is observed in metal gate FinFETs, and the simulations show that this helps recover the electron mobility disadvantage of the (110) FinFET lateral interfaces with respect to (100) interfaces, with no degradation of the hole mobility. The model is then used to systematically explore the impact of stress components in the fin width, height, and length directions on the mobility of both n- and p-type FinFETs and to identify optimal stress configurations. Finally, self-consistent Monte Carlo simulations are used to investigate how the most favorable stress configurations can improve the on current of nanoscale MOSFETs.
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