Wavy Channel TFT-Based Digital Circuits

Amir Hanna; Aftab M. Hussain; Aftab M. Hussain; Aftab M. Hussain; Hesham Omran; Sarah M. Alsharif; Khaled N. Salama; Muhammad Mustafa Hussain

doi:10.1109/TED.2016.2527795

Wavy Channel TFT-Based Digital Circuits

Amir Hanna, Aftab M. Hussain, Aftab M. Hussain, Aftab M. Hussain, Hesham Omran, Sarah M. Alsharif, Khaled N. Salama, Muhammad Mustafa Hussain

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We report a wavy channel (WC) architecture thin-film transistor-based digital circuitry using ZnO as a channel material. The novel architecture allows for extending device width by integrating vertical finlike substrate corrugations giving rise to 50% larger device width, without occupying extra chip area. The enhancement in the output drive current is 100%, when compared with conventional planar architecture for devices occupying the same chip area. The current increase is attributed to both the extra device width and 50% enhancement in field-effect mobility due to electrostatic gating effects. Fabricated inverters show that WC inverters can achieve two times the peak-to-peak output voltage for the same input when compared with planar devices. In addition, WC inverters show 30% faster rise and fall times, and can operate up to around two times frequency of the planar inverters for the same peak-to-peak output voltage. WC NOR circuits have shown 70% higher peak-to-peak output voltage, over their planar counterparts, and WC pass transistor logic multiplexer circuit has shown more than five times faster high-to-low propagation delay compared with its planar counterpart at a similar peak-to-peak output voltage.

Original language	English (US)
Pages (from-to)	1550-1556
Number of pages	7
Journal	IEEE Transactions on Electron Devices
Volume	63
Issue number	4
DOIs	https://doi.org/10.1109/TED.2016.2527795
State	Published - Feb 23 2016

Bibliographical note

KAUST Repository Item: Exported on 2020-10-01
Acknowledged KAUST grant number(s): CRG-1-2012-HUS-008
Acknowledgements: This work was supported by the King Abdullah University of Science and Technology within the Office of Sponsored Research under Grant CRG-1-2012-HUS-008. The review of this paper was arranged by Editor R. M. Todi.

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10.1109/TED.2016.2527795

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title = "Wavy Channel TFT-Based Digital Circuits",

abstract = "We report a wavy channel (WC) architecture thin-film transistor-based digital circuitry using ZnO as a channel material. The novel architecture allows for extending device width by integrating vertical finlike substrate corrugations giving rise to 50% larger device width, without occupying extra chip area. The enhancement in the output drive current is 100%, when compared with conventional planar architecture for devices occupying the same chip area. The current increase is attributed to both the extra device width and 50% enhancement in field-effect mobility due to electrostatic gating effects. Fabricated inverters show that WC inverters can achieve two times the peak-to-peak output voltage for the same input when compared with planar devices. In addition, WC inverters show 30% faster rise and fall times, and can operate up to around two times frequency of the planar inverters for the same peak-to-peak output voltage. WC NOR circuits have shown 70% higher peak-to-peak output voltage, over their planar counterparts, and WC pass transistor logic multiplexer circuit has shown more than five times faster high-to-low propagation delay compared with its planar counterpart at a similar peak-to-peak output voltage.",

author = "Amir Hanna and Hussain, {Aftab M.} and Hussain, {Aftab M.} and Hussain, {Aftab M.} and Hesham Omran and Alsharif, {Sarah M.} and Salama, {Khaled N.} and Hussain, {Muhammad Mustafa}",

note = "KAUST Repository Item: Exported on 2020-10-01 Acknowledged KAUST grant number(s): CRG-1-2012-HUS-008 Acknowledgements: This work was supported by the King Abdullah University of Science and Technology within the Office of Sponsored Research under Grant CRG-1-2012-HUS-008. The review of this paper was arranged by Editor R. M. Todi.",

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AU - Hanna, Amir

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AU - Omran, Hesham

AU - Alsharif, Sarah M.

AU - Salama, Khaled N.

AU - Hussain, Muhammad Mustafa

N1 - KAUST Repository Item: Exported on 2020-10-01 Acknowledged KAUST grant number(s): CRG-1-2012-HUS-008 Acknowledgements: This work was supported by the King Abdullah University of Science and Technology within the Office of Sponsored Research under Grant CRG-1-2012-HUS-008. The review of this paper was arranged by Editor R. M. Todi.

PY - 2016/2/23

Y1 - 2016/2/23

N2 - We report a wavy channel (WC) architecture thin-film transistor-based digital circuitry using ZnO as a channel material. The novel architecture allows for extending device width by integrating vertical finlike substrate corrugations giving rise to 50% larger device width, without occupying extra chip area. The enhancement in the output drive current is 100%, when compared with conventional planar architecture for devices occupying the same chip area. The current increase is attributed to both the extra device width and 50% enhancement in field-effect mobility due to electrostatic gating effects. Fabricated inverters show that WC inverters can achieve two times the peak-to-peak output voltage for the same input when compared with planar devices. In addition, WC inverters show 30% faster rise and fall times, and can operate up to around two times frequency of the planar inverters for the same peak-to-peak output voltage. WC NOR circuits have shown 70% higher peak-to-peak output voltage, over their planar counterparts, and WC pass transistor logic multiplexer circuit has shown more than five times faster high-to-low propagation delay compared with its planar counterpart at a similar peak-to-peak output voltage.

AB - We report a wavy channel (WC) architecture thin-film transistor-based digital circuitry using ZnO as a channel material. The novel architecture allows for extending device width by integrating vertical finlike substrate corrugations giving rise to 50% larger device width, without occupying extra chip area. The enhancement in the output drive current is 100%, when compared with conventional planar architecture for devices occupying the same chip area. The current increase is attributed to both the extra device width and 50% enhancement in field-effect mobility due to electrostatic gating effects. Fabricated inverters show that WC inverters can achieve two times the peak-to-peak output voltage for the same input when compared with planar devices. In addition, WC inverters show 30% faster rise and fall times, and can operate up to around two times frequency of the planar inverters for the same peak-to-peak output voltage. WC NOR circuits have shown 70% higher peak-to-peak output voltage, over their planar counterparts, and WC pass transistor logic multiplexer circuit has shown more than five times faster high-to-low propagation delay compared with its planar counterpart at a similar peak-to-peak output voltage.

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Wavy Channel TFT-Based Digital Circuits

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