• Journal of the Korean Institute of Electrical and Electronic Material Engineers
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• v.25 no.7
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• pp.521-524
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• 2012

We report on variations of electrical properties with different active layer thickness and post-annealing temperature in amorphous In-Ga-Zn-O (IGZO) thin-film transistors (TFTs). In particular, subthreshold swing (SS) of the IGZO-TFTs was improved as increasing the active layer thickness at an given post-annealing temperature, accompanying the negative shift in turn-off voltage. However, as increasing post-annealing temperature, only turn-off voltage was shifted negatively with almost constant SS value. The effect of the active layer thickness and post-annealing temperature on electrical properties, such as SS, field effect mobility and turn-off voltage in IGZO-TFTs has been explained in terms of the variation of trap density in IGZO channel layer and at gate dielectric/IGZO interface.

• JSTS:Journal of Semiconductor Technology and Science
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• v.4 no.2
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• pp.94-99
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• 2004

silicided 50-nm-gate-length n-type Schottky barrier metal-oxide-semiconductor field-effect-transistors (SB-MOSFETs) with 5 nm gate oxide thickness are manufactured. The saturation current is $120{\mu}A/{\mu}m$ and on/off-current ratio is higher than $10^5$ with low leakage current less than $10{\mu}A/{\mu}m$. Novel phenomena of this device are discussed. The increase of tunneling current with the increase of drain voltage is explained using drain induced Schottky barrier thickness thinning effect. The abnormal increase of drain current with the decrease of gate voltage is explained by hole carrier injection from drain into channel. The mechanism of threshold voltage increase in SB-MOSFETs is discussed. Based on the extracted model parameters, the performance of 10-nm-gate-length SB-MOSFETs is predicted. The results show that the subthreshold swing value can be lower than 60 mV/decade.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2017.10a
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• pp.243-244
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• 2017

This paper introduces about the difference between the tunneling currents in the 1D and 2D directions for the calculation of the band-to-band tunneling currents of the tunneling field effect transistors. In the two-dimensional tunneling, diagonal tunneling is not calculated in the one-dimensional tunneling so that more accurate tunneling current can be calculated. Simulation results show that the tunneling in the two - dimensional direction has no effect on the voltage above the threshold voltage, but it affects the subthreshold swing below the threshold voltage.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.16 no.4
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• pp.785-792
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• 2012

In this paper, a current-voltage characteristics of n-channel junctionless and inversion mode(IM) MuGFET, and p-channel junctionless and accumulation mode(AM) MuGFET has been measured and analyzed for the application in high speed and low power switching devices. From the variation of the threshold voltage and the saturation drain current with the substrate bias voltages, their variations in IM devices are larger than junctionless devices for n-channel devices, but their variations in junctioness devices are larger than AM devices for p-channel devices. The variations of transconductance with substrate biases are more significant in p-channel devices than n-channel devices. From the characteristics of subthreshold swing, it was observed that the S value is almost independent on the substrate biases in n-channel devices and p-channel junctionless devices but it is increased with the increase of the substrate biases in p-channel AM devices. For the application in high speed and low power switching devices using the substrate biases, IM device is better than junctionless devices for n-channel devices and junctionless device is better than AM devices for p-channel devices.

• Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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• 2009.11a
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• pp.61-61
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• 2009

P-type SGS-TFTs with 10 ${\mu}m$ channel length and two channel widths; $W_1=5{\mu}m$ and $W_2=10{\mu}m$ which has gate insulator made of 20nm $SiO_2$ and 80nm SiNx was fabricated and the electrical properties of them were measured. The field-effect mobility was increased from 95.84 to 104.19 $cm^2/V-s$ and threshold voltage also increased from -0.802 V to -0.954 V, when channel width is increased from5 ${\mu}m$ to 10 ${\mu}m$. Subthreshold swing decreased from 0.418 to 0.343 V/dec and $I_{on/off}$ ratio increased from $4.77{\times}10^7$ to $7.30{\times}10^7$.

• Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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• 2009.11a
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• pp.62-62
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• 2009

Electrical properties of SGS-TFT with 5/5 ${\mu}m$ channel width and length which gate insulator is made of 20nm $SiO_2$ and 80nm $SiN_x$ was fabricated and measured at various temperatures. The field-effect mobility was decreased from 86.25 to 80.42 $cm^2/Vs$ and threshold voltage also decreased from -1.5792 to -1.0492 V, when temperature is increased from room temperature to $100^{\circ}C$. Subthreshold swing, also, increased from 0.3212 to 0.4818 V/dec and $I_{on/off}$ ratio decreased from $5.05{\times}10^7$ to $6.93{\times}10^5$.

• Proceedings of the Korean Vacuum Society Conference
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• 2015.08a
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• pp.204.1-204.1
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• 2015

We studied the electrical properties and gate bias stress (GBS) stability of thin film transistors (TFTs) with multi-stacked InZnO layers. The InZnO TFTs were fabricated via solution process and the In:Zn molar ratio was 1:1. As the number of InZnO layers was increased, the mobility and the subthreshold swing (S.S) were improved, and the threshold voltage of TFT was reduced. The TFT with three-layered InZnO showed high mobility of $21.2cm^2/Vs$ and S.S of 0.54 V/decade compared the single-layered InZnO TFT with $4.6cm^2/Vs$ and 0.71 V/decade. The three-layered InZnO TFTs were relatively unstable under negative bias stress (NBS), but showed good stability under positive bias stress (PBS).

• Proceedings of the Materials Research Society of Korea Conference
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• 2009.11a
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• pp.30.2-30.2
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• 2009

본 연구에서는 stamping법을이용하여 절연막에 실리콘 나노와이어를 embed시킨 field-effect transistor(FET) 소자의 전기적 특성에 대하여 분석하였다. Stamping법은 나노와이어를 이용한 소자를 제작하는데 있어 쉽고 경제적인 방법으로 최근 많이 사용되고 있는데, 이 방법을 이용하여 나노와이어를 절연막에 embed 시켰다. 이때, 사용한 실리콘 나노와이어는 무전해 식각법을 통하여 합성하였다. 식각 시간을 조절하여 나노와이어의 길이가 $100{\mu}m$ 정도가 되도록 하였고, 나노와이어의 지름은 정제를 통하여 20 ~ 200nm내로 조절하였다. FET 소자의 게이트 절연막은가장 일반적으로 사용되는 SiO2 (200nm)와 고분자 절연막으로 잘 알려진 poly-4-vinylphenol(PVP)를 사용하였다. 실리콘 나노와이어의 전기적 특성을 각각 SiO2무기 절연막에서의 non-embedded상태, PVP 유기 절연막에서의 embedded 상태에서 비교분석 하였다. 전기적 특성은 I-V 측정을 통하여 Ion/Ioff ratio, 이동도, subthreshold swing, threshold voltage값을 평가하였다.

• Proceedings of the KIEE Conference
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• 2011.07a
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• pp.1412-1413
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• 2011

Effects of thermal annealing on electrical characteristics of thin film transistors (TFTs) using hydrogenated zinc oxide (ZnO:H) films as active channel were extensively investigated. The ZnO:H films were deposited at room temperature by RF sputtering. The device parameters of the ZnO:H-based TFTs, such as threshold voltage ($V_{th}$), subthreshold swing (S.S.), and on-off current ratio ($I_{on}/I_{off}$), were characterized in terms of the annealing temperature as well as the gas flow ratio of $H_2$/Ar.

• Journal of Electrical Engineering and Technology
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• v.12 no.6
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• pp.2353-2358
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• 2017

A femtosecond laser pre-annealing process based on indium zinc oxide (IZO) thin-film transistors (TFTs) is fabricated. We demonstrate a stable pre-annealing process to analyze surface structure change of thin films, and we maintain electrical stability and improve electrical performance. Furthermore, dynamic electrical characteristics of the IZO TFTs were investigated. Femtosecond laser pre-annealing process-based IZO TFTs exhibit a field-effect mobility of $3.75cm^2/Vs$, an $I_{on}/I_{off}$ ratio of $1.77{\times}10^5$, a threshold voltage of 1.13 V, and a subthreshold swing of 1.21 V/dec. And the IZO-based inverter shows a fast switching behavior response. From this study, IZO TFTs from using the femtosecond laser annealing technique were found to strongly affect the electrical performance and charge transport dynamics in electronic devices.