Nonvolatile reversible capacitance changes through filament formation in a floating-gate metal-oxide-semiconductor capacitor with Ag/CeOx/Pt/HfOx/n-Si structure

Nonvolatile and reversible capacitance changes are demonstrated in a floating-gate metal-oxide-semiconductor (FG-MOS) capacitor with a Ag-control-gate/CeOx-control-oxide/Pt-floating-gate/HfOx-tunneling-oxide/n-Si structure. Different from the conventional floating-gate MOS field-effect-transistor (M...

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Veröffentlicht in:	Applied physics letters 2019-08, Vol.115 (7)
Hauptverfasser:	Kim, Minju, Beom, Keonwon, Lee, Hyerin, Kang, Chi Jung, Yoon, Tae-Sik
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Capacitance Capacitors Charging Crosstalk Electrical properties Floating structures Immunity Memory devices Metal oxide semiconductors MOSFETs Platinum Programmable logic devices Rupturing Silver Threshold voltage
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creator	Kim, Minju Beom, Keonwon Lee, Hyerin Kang, Chi Jung Yoon, Tae-Sik
description	Nonvolatile and reversible capacitance changes are demonstrated in a floating-gate metal-oxide-semiconductor (FG-MOS) capacitor with a Ag-control-gate/CeOx-control-oxide/Pt-floating-gate/HfOx-tunneling-oxide/n-Si structure. Different from the conventional floating-gate MOS field-effect-transistor (MOSFET) operating with a threshold voltage shift by electrical charging in the floating-gate (charge storage node), the proposed device operates with the change of gate oxide capacitance as one of the parameters determining the electrical properties of MOSFET. Applying positive voltage to the Ag control-gate forms a conducting filament in the Ag/CeOx/Pt stack and consequently increases the gate oxide capacitance. The accumulation capacitance increases from the capacitance of serial capacitors consisting of Ag/CeOx/Pt and Pt/HfOx/n-Si before the filament formation to that of a single capacitor of Pt/HfOx/n-Si after the filament formation. The capacitance is reversibly decreased to the initial value by rupturing the filament upon applying negative voltage. The change of capacitance is stable over time with the retention >90% for 12 h of measured time. These noncharge-storage-based nonvolatile and reversible changes in the gate oxide capacitance through the filament formation would modulate the MOSFET properties with the advantages of better uniformity, superior immunity to the radiation, and less cross talk between adjacent devices for the application to nonvolatile memory and programmable logic devices.
doi_str_mv	10.1063/1.5109929
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Different from the conventional floating-gate MOS field-effect-transistor (MOSFET) operating with a threshold voltage shift by electrical charging in the floating-gate (charge storage node), the proposed device operates with the change of gate oxide capacitance as one of the parameters determining the electrical properties of MOSFET. Applying positive voltage to the Ag control-gate forms a conducting filament in the Ag/CeOx/Pt stack and consequently increases the gate oxide capacitance. The accumulation capacitance increases from the capacitance of serial capacitors consisting of Ag/CeOx/Pt and Pt/HfOx/n-Si before the filament formation to that of a single capacitor of Pt/HfOx/n-Si after the filament formation. The capacitance is reversibly decreased to the initial value by rupturing the filament upon applying negative voltage. The change of capacitance is stable over time with the retention >90% for 12 h of measured time. 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Different from the conventional floating-gate MOS field-effect-transistor (MOSFET) operating with a threshold voltage shift by electrical charging in the floating-gate (charge storage node), the proposed device operates with the change of gate oxide capacitance as one of the parameters determining the electrical properties of MOSFET. Applying positive voltage to the Ag control-gate forms a conducting filament in the Ag/CeOx/Pt stack and consequently increases the gate oxide capacitance. The accumulation capacitance increases from the capacitance of serial capacitors consisting of Ag/CeOx/Pt and Pt/HfOx/n-Si before the filament formation to that of a single capacitor of Pt/HfOx/n-Si after the filament formation. The capacitance is reversibly decreased to the initial value by rupturing the filament upon applying negative voltage. The change of capacitance is stable over time with the retention >90% for 12 h of measured time. 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Different from the conventional floating-gate MOS field-effect-transistor (MOSFET) operating with a threshold voltage shift by electrical charging in the floating-gate (charge storage node), the proposed device operates with the change of gate oxide capacitance as one of the parameters determining the electrical properties of MOSFET. Applying positive voltage to the Ag control-gate forms a conducting filament in the Ag/CeOx/Pt stack and consequently increases the gate oxide capacitance. The accumulation capacitance increases from the capacitance of serial capacitors consisting of Ag/CeOx/Pt and Pt/HfOx/n-Si before the filament formation to that of a single capacitor of Pt/HfOx/n-Si after the filament formation. The capacitance is reversibly decreased to the initial value by rupturing the filament upon applying negative voltage. The change of capacitance is stable over time with the retention >90% for 12 h of measured time. 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source	AIP Journals Complete; Alma/SFX Local Collection
subjects	Applied physics Capacitance Capacitors Charging Crosstalk Electrical properties Floating structures Immunity Memory devices Metal oxide semiconductors MOSFETs Platinum Programmable logic devices Rupturing Silver Threshold voltage
title	Nonvolatile reversible capacitance changes through filament formation in a floating-gate metal-oxide-semiconductor capacitor with Ag/CeOx/Pt/HfOx/n-Si structure
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