Artigos
URI permanente para esta coleçãohttps://repositorio.fei.edu.br/handle/FEI/798
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Resultados da Pesquisa
- Modeling the interface traps-related low frequency noise in triple-gate SOI junctionless nanowire transistors(2019) Trevisoli R.; Doria R.T.; Barraud S.; Pavanello M.A.© 2019 Elsevier B.V.The aim of this work is to propose a semi-analytical model for the low frequency noise caused by interface traps in Triple-Gate Junctionless Nanowire Transistors. The proposed model is based on a drain current model, which includes short channel effects influence. The surface potential and the occupied trap density equations are solved self consistently to obtain the traps influence in the static drain current, which is used to determine the trap-related noise. In this work, the low frequency noise of traps in discrete levels is analyzed. The model has been validated with 3D simulations considering different devices characteristics, biases and trap levels. Experimental results have also been used to demonstrate the model suitability.
- Analysis of the substrate bias effect on the interface trapped charges in junctionless nanowire transistors through low-frequency noise characterization(2017) Doria R.T.; Trevisoli R.; de Souza M.; Barraud S.; Vinet M.; Faynot O.; Pavanello M.A.© 2017 Elsevier B.V.This work presents, for the first time, an experimental analysis of the low-frequency noise and the effective trap density dependence of junctionless nanowire transistors (JNTs) on the substrate bias. The study has been performed for devices with different channel lengths and doping concentrations biased close to the threshold and deep in linear regime. It has been shown that the surface potential of JNTs is strongly influenced by the substrate bias even above threshold. Thus, the drain current noise spectral density and the effective trap density can be improved or degraded depending on the bias applied to the substrate of the devices. Additionally, it is shown that, the variation on the substrate bias enables the evaluation of traps with different activation energy ranges, which is more evident in heavier doped devices due to the higher threshold voltage sensitivity to the substrate bias.
- In-depth low frequency noise evaluation of substrate rotation and strain engineering in N-type triple gate SOI Finfets(2015) Doria R.T.; De Souza M.A.S.; Martino J.A.; Simoen E.; Claeys C.; Pavanello M.A.© 2015 Elsevier B.V. All rights reserved.This work presents an experimental analysis of the low-frequency noise and the effective trap density of conventional, strained, rotated and strained-rotated SOI n-type FinFETs, respectively, for several fin widths biased at different gate voltages. Additionally, the profile of the effective trap density is presented along the depth of the gate dielectric of the devices. It is shown that strained devices present higher noise than conventional ones, independent on the fin width, which can be explained by poorer interface quality observed in strained devices. On the other hand, the low frequency noise of narrow rotated devices, where the main conduction path changes from top to sidewalls, has shown to reduce as the interface integrity is improved by substrate rotation. All the evaluated devices presented 1/f noise as the dominant noise component up to 1 kHz.
- Trap density characterization through low-frequency noise in junctionless transistors(2013) Doria R.T.; Trevisoli R.D.; De Souza M.; Pavanello M.A.This work evaluates, for the first time, the trap density of Junctionless Nanowire Transistors (JNTs) of two technologies produced with different gate dielectrics through the low-frequency noise (LFN) characterization. Along the work, the LFN resultant from both devices was compared in linear and saturation regimes for different gate biases, showing that these devices can exhibit either 1/f or Lorentzian as the dominant noise source depending on the technology and gate bias. Such analysis showed that devices with SiO2 gate dielectric have presented only one corner frequency over the whole frequency range whereas two corner frequencies with different time constants could be observed in devices with HfSiON gate dielectric. The trap density of both devices showed to be similar to the values reported for inversion mode devices in different recent papers, in the order of 1016 cm-3 eV-1 and 1019 cm-3 eV-1, for SiO2 and HfSiON gate dielectrics, respectively.© 2013 Elsevier B.V.All rights reserved.