An Above Threshold Model for Short-Channel DG MOSFETs

An above-threshold I-V model is developed for short-channel double-gate (DG) MOSFETs. It is a non-gradual channel approximation (non-GCA) model that takes into account the contribution to carrier density from the encroachment of source-drain bands into the channel. At low-drain bias voltages, the ef...

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Veröffentlicht in:	IEEE transactions on electron devices 2021-08, Vol.68 (8), p.3734-3739
Hauptverfasser:	Hong, David Chuyang, Taur, Yuan
Format:	Artikel
Sprache:	eng
Schlagworte:	Boundary conditions Carrier density Depletion Double-gate (DG) MOSFETs model Electric potential Logic gates Mathematical model MOSFET MOSFETs Semiconductor device modeling Semiconductor process modeling short-channel effect (SCE) source encroachment
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creator	Hong, David Chuyang Taur, Yuan
description	An above-threshold I-V model is developed for short-channel double-gate (DG) MOSFETs. It is a non-gradual channel approximation (non-GCA) model that takes into account the contribution to carrier density from the encroachment of source-drain bands into the channel. At low-drain bias voltages, the effect appears as a gate-voltage-dependent reduction of channel resistance, with stronger effects at low gate overdrives. At high-drain biases, the intersection of source band encroachment with the gate-controlled channel potential leads to a point of virtual cathode a small distance from the source. By incorporating the depletion of carriers in the source and drain regions into the boundary conditions, the {I}_{\text {ds}}-{V}_{\text {ds}} and {I}_{\text {ds}}-{V}_{\text {gs}} characteristics generated by the model are shown to be consistent with TCAD simulations.
doi_str_mv	10.1109/TED.2021.3092310
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It is a non-gradual channel approximation (non-GCA) model that takes into account the contribution to carrier density from the encroachment of source-drain bands into the channel. At low-drain bias voltages, the effect appears as a gate-voltage-dependent reduction of channel resistance, with stronger effects at low gate overdrives. At high-drain biases, the intersection of source band encroachment with the gate-controlled channel potential leads to a point of virtual cathode a small distance from the source. 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It is a non-gradual channel approximation (non-GCA) model that takes into account the contribution to carrier density from the encroachment of source-drain bands into the channel. At low-drain bias voltages, the effect appears as a gate-voltage-dependent reduction of channel resistance, with stronger effects at low gate overdrives. At high-drain biases, the intersection of source band encroachment with the gate-controlled channel potential leads to a point of virtual cathode a small distance from the source. 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subjects	Boundary conditions Carrier density Depletion Double-gate (DG) MOSFETs model Electric potential Logic gates Mathematical model MOSFET MOSFETs Semiconductor device modeling Semiconductor process modeling short-channel effect (SCE) source encroachment
title	An Above Threshold Model for Short-Channel DG MOSFETs
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