TY - JOUR
T1 - Compact model strategy of metal-gate work-function variation for ultrascaled FinFET and vertical GAA FETs
AU - Ko, Kyul
AU - Kang, Myounggon
AU - Jeon, Jongwook
AU - Shin, Hyungcheol
N1 - Publisher Copyright:
© 2019 IEEE.
PY - 2019/3
Y1 - 2019/3
N2 - In this paper, we develop an accurate compact model for work-function variation (WFV)-induced threshold voltage (V th ) variations of various 5-nm candidates, in this case, Si SOI FinFETs, vertical gate-all-around nanowire FETs, and nanoplate FETs. Using the typical probability distribution function model to predict the effect of WFV, due to the ideal condition, an error occurs in ultrascaled devices. Therefore, to analyze the influence of WFV accurately, the error rate (α) is corrected by considering irregular grain patterns (Voronoi method). In addition, the total number of grains on the metal surface can be calculated while considering the effective grain size and gate area due to the structural characteristics of the device. Finally, the model is benchmarked against 3-D TCAD simulations to demonstrate excellent accuracy [1.53% error in σ(V th )]-Moreover, the accuracy is improved by more than 15 times compared with the existing analytical models. As a result, the proposed model based on binomial distribution is able to analyze the effect of WFV at a significantly lower computational cost than 3-D TCAD simulations.
AB - In this paper, we develop an accurate compact model for work-function variation (WFV)-induced threshold voltage (V th ) variations of various 5-nm candidates, in this case, Si SOI FinFETs, vertical gate-all-around nanowire FETs, and nanoplate FETs. Using the typical probability distribution function model to predict the effect of WFV, due to the ideal condition, an error occurs in ultrascaled devices. Therefore, to analyze the influence of WFV accurately, the error rate (α) is corrected by considering irregular grain patterns (Voronoi method). In addition, the total number of grains on the metal surface can be calculated while considering the effective grain size and gate area due to the structural characteristics of the device. Finally, the model is benchmarked against 3-D TCAD simulations to demonstrate excellent accuracy [1.53% error in σ(V th )]-Moreover, the accuracy is improved by more than 15 times compared with the existing analytical models. As a result, the proposed model based on binomial distribution is able to analyze the effect of WFV at a significantly lower computational cost than 3-D TCAD simulations.
KW - Compact model (CM)
KW - FinFET
KW - Gate-all-around (GAA)
KW - Vertical device
KW - Work-function variation (WFV)
UR - http://www.scopus.com/inward/record.url?scp=85062293340&partnerID=8YFLogxK
U2 - 10.1109/TED.2019.2891677
DO - 10.1109/TED.2019.2891677
M3 - Article
AN - SCOPUS:85062293340
SN - 0018-9383
VL - 66
SP - 1613
EP - 1616
JO - IEEE Transactions on Electron Devices
JF - IEEE Transactions on Electron Devices
IS - 3
M1 - 8627378
ER -