Investigation of Lateral Trap Position by Random Telegraph Signal Analysis in Moderate Inversion in n-Channel MOSFETs

Chen, Ching En; Chang, Ting Chang; You, Bo; Lo, Wen Hung; Ho, Shinn‐Ying; Dai, Chih Hao; Tsai, Jyun Yu; Chen, Hua Mao; Liu, Guan Ru; Tai, Ya‐Hsiang; Tseng, Tseung‐Yuen

doi:10.1149/2.011311ssl

ECS Solid State Letters

2013

DOI: 10.1149/2.011311ssl

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Investigation of Lateral Trap Position by Random Telegraph Signal Analysis in Moderate Inversion in n-Channel MOSFETs

Ching En Chen

Ting Chang Chang

Bo You

et al.

Abstract: This paper investigates the trap position by random telegraph signal (RTS) analysis in moderate inversion in partially depleted silicon-on-insulator n-channel metal-oxide-semiconductor field-effect transistors. In the diffusion current-dominated region, the electron concentration distribution is more non-uniform along the channel than the one in the drift current-dominated region. In the diffusion region, the application of drain (source) voltage can influence the potential at the drain (source) side only. Acc… Show more

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Cited by 2 publications

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“…[10][11][12][13] The RTS phenomenon is commonly caused by a carrier that has been captured and emitted by an oxide trap. Although researches on lateral trap position determined by 2-level channel current RTS (2-RTS) have been previously reported, [13][14][15] there are few reports that study the trap position in multilevel RTS. In this work, the located regions of lateral trap position are analyzed by 3-level channel current RTS (3-RTS) with and without interchanged S/D (reverse and forward operations).…”

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A Method to Determine the Located Region of Lateral Trap Position by Analysis of Three-Level Random Telegraph Signals in n-MOSFETs

Chen

Chang

You

et al. 2015

ECS Solid State Letters

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This paper introduces a method to determine the located region of trap position by the analysis of three-level random telegraph signal (RTS) in partially-depleted silicon-on-insulator n-channel metal-oxide-semiconductor field-effect-transistors. For the cases of two traps, the average time at the 2 nd level ( τ 2 ) is composed of average emission time of one trap and average capture time of the other. Comparison and analysis of τ 2 curves varying with gate voltage in RTS measurements with and without interchanged source/drain can clarify the located regions of the two traps. Moreover, the simplified equations are also considered and used to confirm the trap positions.Silicon-on-insulator (SOI) MOSFETs have been attracted attention recently due to their lower power consumption, high speed, increased circuit packing density and absence of CMOS latch-up. In addition, due to their power management characteristics and ability to switch to an improved operation speed in large-scale devices, SOI MOSFETs, memory devices, 1-3 and thin-film transistors (TFTs) 4-6 can be integrated into mobile electronic products. However, the floating body effect and self-heating effect 7-9 are inherent disadvantages in SOI devices. When devices are scaled down to deep sub-micrometer, the random telegraph signal (RTS) becomes a major issue and influences the performance of MOSFETs. 10-13 The RTS phenomenon is commonly caused by a carrier that has been captured and emitted by an oxide trap. Although researches on lateral trap position determined by 2-level channel current RTS (2-RTS) have been previously reported, [13][14][15] there are few reports that study the trap position in multilevel RTS. In this work, the located regions of lateral trap position are analyzed by 3-level channel current RTS (3-RTS) with and without interchanged S/D (reverse and forward operations). Then, according to the Shockley-Read-Hall (SRH) model, the located regions of the oxide trap are clarified by the comparisons between the average times at the medium channel current ( τ 2 ), or so-called the 2 nd level, under forward and reverse operations. Furthermore, the simplified equations, which are based on the SRH model, are used to confirm these trap positions. ExperimentalThe PD SOI nMOSFETs used in this study were fabricated by SOI technology with a T-gate structure. The thickness of silicon film and buried oxide are 0.15 μm and 1 μm, respectively. The gate oxide with thickness of 100 Å was grown on silicon film with a channel doping concentration of about 1.3 × 10 18 cm −3 . In this paper, the device has dimension of width/length = 1 μm/0.35 μm. The RTS measurements were performed by an Agilent B1500A semiconductor device analyzer, an Agilent B1530A Waveform-Generator/FastMeasurement-Unit (WGFMU) and a Cascade Microtech M150 measurement platform. Results and DiscussionFigure 1 shows the V G dependence on drain current RTS (I D -RTS) from V G = 0.45 V to 0.75 V with V D = 50 mV for a period of 100 * Electrochemical Society Active Member. z E-mail: tcchang3708@gma...

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A Method to Determine the Located Region of Lateral Trap Position by Analysis of Three-Level Random Telegraph Signals in n-MOSFETs

Chen

Chang

You

et al. 2015

ECS Solid State Letters

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Analysis of Oxide Trap Characteristics by Random Telegraph Signals in nMOSFETs With HfO₂-Based Gate Dielectrics

Chen

Chang

You

et al. 2016

IEEE Electron Device Lett.

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Investigation of Lateral Trap Position by Random Telegraph Signal Analysis in Moderate Inversion in n-Channel MOSFETs

Cited by 2 publications

References 21 publications

A Method to Determine the Located Region of Lateral Trap Position by Analysis of Three-Level Random Telegraph Signals in n-MOSFETs

A Method to Determine the Located Region of Lateral Trap Position by Analysis of Three-Level Random Telegraph Signals in n-MOSFETs

Analysis of Oxide Trap Characteristics by Random Telegraph Signals in nMOSFETs With HfO₂-Based Gate Dielectrics

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Investigation of Lateral Trap Position by Random Telegraph Signal Analysis in Moderate Inversion in n-Channel MOSFETs

Cited by 2 publications

References 21 publications

A Method to Determine the Located Region of Lateral Trap Position by Analysis of Three-Level Random Telegraph Signals in n-MOSFETs

A Method to Determine the Located Region of Lateral Trap Position by Analysis of Three-Level Random Telegraph Signals in n-MOSFETs

Analysis of Oxide Trap Characteristics by Random Telegraph Signals in nMOSFETs With HfO2-Based Gate Dielectrics

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Analysis of Oxide Trap Characteristics by Random Telegraph Signals in nMOSFETs With HfO₂-Based Gate Dielectrics