TY - JOUR
T1 - Physics-based bias-dependent compact modeling of 1/f noise in single- to few-layer 2D-FETs
AU - Mavredakis, Nikolaos
AU - Pacheco-Sanchez, Anibal
AU - Alam, Md Hasibul
AU - Guimerà-Brunet, Anton
AU - Martinez, Javier
AU - Garrido, Jose Antonio
AU - Akinwande, Deji
AU - Jiménez, David
N1 - Publisher Copyright:
© 2023 The Royal Society of Chemistry.
PY - 2023/3/15
Y1 - 2023/3/15
N2 - 1/f noise is a critical figure of merit for the performance of transistors and circuits. For two-dimensional devices (2D-FETs), and especially for applications in the GHz range where short-channel FETs are required, the velocity saturation (VS) effect can result in the reduction of 1/f noise at high longitudinal electric fields. A new physics-based compact model has been for the first time introduced for single- to few-layer 2D-FETs in this study, precisely validating 1/f noise experiments for various types of devices. The proposed model mainly accounts for the measured 1/f noise bias dependence as the latter is defined by different physical mechanisms. Thus, analytical expressions are derived, valid in all regions of operation in contrast to conventional approaches available in the literature so far, accounting for carrier number fluctuation (ΔN), mobility fluctuation (Δμ) and contact resistance (ΔR) effects based on the underlying physics that rules these devices. The ΔN mechanism due to trapping/detrapping together with an intense Coulomb scattering effect dominates the 1/f noise from the medium to the strong accumulation region while Δμ has also been demonstrated to modestly contribute in the subthreshold region. ΔR can also be significant in a very high carrier density. The VS induced reduction of 1/f noise measurements at high electric fields was also remarkably captured by the model. The physical validity of the model can also assist in extracting credible conclusions when conducting comparisons between experimental data from devices with different materials or dielectrics.
AB - 1/f noise is a critical figure of merit for the performance of transistors and circuits. For two-dimensional devices (2D-FETs), and especially for applications in the GHz range where short-channel FETs are required, the velocity saturation (VS) effect can result in the reduction of 1/f noise at high longitudinal electric fields. A new physics-based compact model has been for the first time introduced for single- to few-layer 2D-FETs in this study, precisely validating 1/f noise experiments for various types of devices. The proposed model mainly accounts for the measured 1/f noise bias dependence as the latter is defined by different physical mechanisms. Thus, analytical expressions are derived, valid in all regions of operation in contrast to conventional approaches available in the literature so far, accounting for carrier number fluctuation (ΔN), mobility fluctuation (Δμ) and contact resistance (ΔR) effects based on the underlying physics that rules these devices. The ΔN mechanism due to trapping/detrapping together with an intense Coulomb scattering effect dominates the 1/f noise from the medium to the strong accumulation region while Δμ has also been demonstrated to modestly contribute in the subthreshold region. ΔR can also be significant in a very high carrier density. The VS induced reduction of 1/f noise measurements at high electric fields was also remarkably captured by the model. The physical validity of the model can also assist in extracting credible conclusions when conducting comparisons between experimental data from devices with different materials or dielectrics.
UR - http://www.scopus.com/inward/record.url?scp=85151502112&partnerID=8YFLogxK
UR - https://www.mendeley.com/catalogue/3b366351-a57f-3ba1-bf7d-c177a813280f/
U2 - 10.1039/D3NR00922J
DO - 10.1039/D3NR00922J
M3 - Article
SN - 2040-3364
SP - 6853
EP - 6863
JO - Nanoscale
JF - Nanoscale
IS - 14
ER -