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"GZO"

Effect of Concurrent Low-Temp Plasma Annealing on a-IGZO TFT Performance Over Time
Jeong Hun Choi, Jae-yun Lee, Beom Gu Lee, Jeong Moo Seo, Sung-jin Kim
J Electr Electron Mater 2025;38(3):265-271.   Published online May 1, 2025
DOI: https://doi.org/10.4313/JKEM.2025.38.3.4
Recently, oxide semiconductors have assumed a pivotal role in electronic displays and transparent electronic devices such as amorphous indium gallium zinc oxide (a-IGZO), characterized by high electron mobility and excellent stability. a- IGZO is very suitable for next-generation applications such as flexible displays because it is possible to manufacture highperformance transistors even at low temperatures. However, since the electrical properties tend to deteriorate in hightemperature environments, research aimed at improving thermal stability is needed. In this study, a low-temperature plasma annealing process was introduced to improve the high-temperature stability of the a-IGZO thin film. This process enhances electron mobility by reducing defects in the a-IGZO film and provides stable device performance even under high-temperature conditions. As a result of the experiments of 5 min, 10 min, 15 min, and 20 min, the a-IGZO TFT, which was subjected to plasma annealing at 160℃ for 5 min, showed the best electrical performance, especially in charge mobility and current-voltage characteristics. The technical potential for improving the performance of a-IGZO-based display device was emphasized, and the foundation for applying this power generation to flexible displays and next-generation electronic devices was laid. Future research will focus on determining the optimal annealing conditions by exploring various temperature ranges and plasma parameters to integrate these results into the actual device manufacturing process. These efforts are expected advance significantly to advancing next-generation high-performance display technology.
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Simultaneous Low-Temperature Plasma Annealing Process for Enhancing the Electrical Performance of a-IGZO Thin Film Transistors
Jung Hun Choi, Jae-yun Lee, Beom Gu Lee, Jung Moo Seo, Sung-jin Kim
J Electr Electron Mater 2024;37(6):630-636.   Published online November 1, 2024
DOI: https://doi.org/10.4313/JKEM.2024.37.6.8
The display industry has recently been at the forefront of innovative advancements in modern electronic devices. Technological progress such as flexible display holds significant potential across various application fields, particularly in wearable devices and rollable displays. A low-temperature process is essential for fabricating such displays. One of the key technologies in displays is the thin film transistor (TFT), with amorphous indium gallium zinc oxide (a-IGZO) receiving particular attention. a-IGZO is widely applied in high-performance displays due to its high charge mobility and stability. While a thermal treatment above 350℃ is typically required to maximize the electrical performance of a-IGZO TFTs, such high temperatures pose challenges for utilizing polymer substrates like plastics. Here, we thesis investigates the simultaneous lowtemperature plasma annealing process to develop next-generation high-performance flexible display devices. To define the optimal temperature, devices were fabricated and analyzed at varying temperatures of 40℃, 80℃, 120℃, and 160℃. Experimental results indicated that devices fabricated at 160℃ and 80℃ exhibited superior performance, with those at 160℃ demonstrating better performance in terms of current ratio, threshold voltage, and subthreshold swing. These findings confirm that the simultaneous low-temperature plasma annealing process is effective for next-generation high-performance displays.
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Recent Advances in a-IGZO Thin Film Transistor Devices: A Short Review
Jingwen Chen, Fucheng Wang, Yifan Hu, Jaewoong Cho, Yeojin Jeong, Duy Phong Pham, Junsin Yi
J Electr Electron Mater 2023;36(5):463-473.   Published online September 1, 2023
DOI: https://doi.org/10.4313/JKEM.2023.36.5.5
In recent years, the transparent amorphous oxide thin film transistor represented by indium-gallium-zinc-oxide (IGZO) has become the first choice of the next generation of integrated circuit control components. This article contributes an overview of IGZO thin-film transistors (TFTs), including their fundamental principles and recent advancements. The paper outlines various TFT structures and places emphasis on the fabrication process of the active layer. The result showed that the size of the active layer including the length-to-width ratio and the width could have a significant effect on the mobility. And the process of TFT could influence the crystal structure of IGZO thin film. Furthermore, the article presents an overview of recent applications of IGZO TFTs, such as their use in display drivers and TFT memories. At last, the future development of IGZO TFT is forecasted in this paper.
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Structural, Electrical, and Optical Properties of AGZO Thin Films Using RF Magnetron Sputtering System Under Ar Flow Rates
Seok-hyeon Jang, Deok Kyu Kim
J Electr Electron Mater 2022;35(1):32-36.   Published online January 1, 2022
DOI: https://doi.org/10.4313/JKEM.2022.35.1.5
AGZO thin films were deposited on glass substrates using RF magnetron sputtering system under Ar flow rates, and their structural, electrical, and optical properties were analyzed systematically. As a result of the XRD pattern, the peak of the (002) (2θ≈33.7˚) orientation was observed, and it was found to have a hexagonal wurtzite structure. The sheet resistance of Ar 5 sccm was 3.073×102 Ω/sq and showed the best electrical properties because of the improvement of mobility due to the increase of the grain size and the variation of RMS roughness. In addition, the average transmittance was more than 90% for all samples, which demonstrated good optical properties. It is expected that the TCO characteristics can be improved by controlling Ar flow rates, and this will increase the efficiency of photoelectronic devices such as OLED and solar cells.
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Effects of Plasma Treatment on the Reliability of a-IGZO TFT
Dongxu Xin, Ziyang Cui, Taeyong Kim, Junsin Yi
J Electr Electron Mater 2021;34(2):85-89.   Published online March 1, 2021
DOI: https://doi.org/10.4313/JKEM.2021.34.2.1
High reliability thin film transistors are important factors for next-generation displays. The reliability of transparent a-IGZO semiconductors is being actively studied for display applications. A plasma treatment can fill the oxygen vacancies in the channel layer and the channel layer/insulating layer interface so that the device can work stably under a bias voltage. This paper studies the effect of plasma treatment on the performance of a-IGZO TFT devices. The influence of different plasma gases on the electrical parameters of device and its working reliability are reviewed. The article mentions argon, fluorine, hydrogen and several ways of processing in the atmosphere. Among these methods, F (fluorine) plasma treatment can maximize equipment reliability. It is expected that the presented results will form a basis for further research to improve the reliability of a-IGZO TFT.
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Analysis of the Output Characteristics of IGZO TFT with Double Gate Structure
Ji Won Kim, Kee Chan Park, Yong Sang Kim, Jae Hong Jeon
J Electr Electron Mater 2020;33(4):281-285.   Published online July 1, 2020
DOI: https://doi.org/10.4313/JKEM.2021.33.4.6
Oxide semiconductor devices have become increasingly important because of their high mobility and good uniformity. The channel length of oxide semiconductor thin film transistors (TFTs) also shrinks as the display resolution increases. It is well known that reducing the channel length of a TFT is detrimental to the current saturation because of drain-induced barrier lowering, as well as the movement of the pinch-off point. In an organic light-emitting diode (OLED), the lack of current saturation in the driving TFT creates a major problem in the control of OLED current. To obtain improved current saturation in short channels, we fabricated indium gallium zinc oxide (IGZO) TFTs with single gate and double gate structures, and evaluated the electrical characteristics of both devices. For the double gate structure, we connected the bottom gate electrode to the source electrode, so that the electric potential of the bottom gate was fixed to that of the source. We denote the double gate structure with the bottom gate fixed at the source potential as the BGFP (bottom gate with fixed potential) structure. For the BGFP TFT, the current saturation, as determined by the output characteristics, is better than that of the conventional single gate TFT. This is because the change in the source side potential barrier by the drain field has been suppressed.
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IGZO TFT Stability Improvement Based on Various Passivation Materials
Jaemin Kim, Jinsu Park, Geonju Yoon, Jaehyun Cho, Sangwoo Bae, Jinseok Kim, Keewon Kwon, Youn-jung Lee, Junsin Yi
J Electr Electron Mater 2020;33(1):6-9.   Published online January 1, 2020
DOI: https://doi.org/10.4313/JKEM.2021.33.1.2
Thin film transistors (TFTs) with large-area, high mobility, and high reliability are important factors for next-generation displays. In particular, thin transistors based on IGZO oxide semiconductors are being actively researched for this application. In this study, several methods for improving the reliability of a-IGZO TFTs by applying various materials on a passivation layer are investigated. In the literature, inorganic SiO2, TiO2, Al2O3, ZTSO, and organic CYTOP have been used for passivation. In the case of Al2O3, excellent stability is exhibited compared to the non-passivation TFT under the conditions of negative bias illumination stress (NBIS) for 3 wavelengths (R, G, B). When CYTOP passivation, SiO2 passivation, and non-passivation devices were compared under the same positive bias temperature stress (PBTS), the Vth shifts were 2.8 V, 3.3 V, and 4.5 V, respectively. The Vth shifts of TiO2 passivation and non-passivation devices under the same NBTS were -2.2 V and -3.8 V, respectively. It is expected that the presented results will form the basis for further research to improve the reliability of a-IGZO TFT.
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Research Trends for Improvement of NBIS Instability in Amorphous In-Ga-ZnO Based Thin-Film Transistors
Geonju Yoon, Jinsu Park, Jaemin Kim, Jaehyun Cho, Sangwoo Bae, Jinseok Kim, Hyun-hoo Kim, Junsin Yi
J Electr Electron Mater 2019;32(5):371-375.   Published online September 1, 2019
Developing a thin-film transistor with characteristics such as a large area, high mobility, and high reliability are key elements required for the next generation on displays. In this paper, we have investigated the research trends related to improving the reliability of oxide-semiconductor-based thin-film transistors, which are the primary focus of study in the field of optical displays. It has been reported that thermal treatment in a high-pressure oxygen atmosphere reduces the threshold voltage shift from -7.1 V to -1.9 V under NBIS. Additionally, a device with a SiO2/Si3N4 dual-structure has a lower threshold voltage (-0.82 V) under NBIS than a single-gate-insulator-based device (-11.6 V). The dual channel structure with different oxygen partial pressures was also confirmed to have a stable threshold voltage under NBIS. These can be considered for further study to improve the NBIS problem.
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Study on the Properties of ZnO:Ga Thin Films with Substrate Temperatures
Jeong-gyoo Kim, Ki-cheol Park
J Electr Electron Mater 2017;30(12):794-799.   Published online December 1, 2017
Ga-doped ZnO (GZO) films were deposited by an RF magnetron sputtering method on glass substrates using ZnO as a target containing 5 wt% Ga2O3 powder (for Ga doping). The structural, electrical, and optical properties of the GZO thin films were investigated as a function of the substrate temperatures. The deposition rate decreased with increasing substrate temperatures from room temperature to 350℃. The films showed typical orientation with the c-axis vertical to the glass substrates and the grain size increased up to a substrate temperature of 300℃ but decreased beyond 350℃. The resistivity of GZO thin films deposited at the substrate temperature of 300℃ was 7×10-4 Ωcm, and it showed a dependence on the carrier concentration and mobility. The optical transmittances of the films with thickness of 3,000 Å were above 80% in the visible region, regardless of the substrate temperatures.
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Regular Paper : Performance Improvement of Amorphous In-Ga-Zn-O Thin-film Transistors Using Different Source/drain Electrode Materials
Seung-tae Kim, Won-ju Cho
J Electr Electron Mater 2016;29(2):69-74.   Published online February 1, 2016
In this study, we proposed an a-IGZO (amorphous In-Ga-Zn-O) TFT (thin-film transistor) with off-planed source/drain structure. Furthermore, two different electrode materials (ITO and Ti) were applied to the source and drain contacts for performance improvement of a-IGZO TFTs. When the ITO with a large work-function and the Ti with a small work-function are applied to drain electrode and source contact, respectively, the electrical performances of a-IGZO TFTs were improved; an increased driving current, a decreased leakage current, a high on-off current ratio, and a reduced subthreshold swing. As a result of gate bias stress test at various temperatures, the off-planed S/D a-IGZO TFTs showed a degradation mechanism due to electron trapping and both devices with ITO-drain or Ti-drain electrode revealed an equivalent instability.
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Regular Paper : Fabrication and Electrical Characteristics of Transparent and Bendable a-IGZO Thin-film Transistors
Suk Hyung Park, Kyoung Ah Cho, Hyun Gon Oh, Sang Sig Kim
J Electr Electron Mater 2016;29(2):120-124.   Published online February 1, 2016
In this study, we fabricate transparent and bendable a-IGZO (amorphous indium gallium zinc oxide) TFTs (thin-film transistors) with a-IZO (amorphous indium zinc oxide) transparent electrodes on plastic substrates and investigate their electrical characteristics under bending states. Our a-IGZO TFTs show a high transmittance of 82% at a wavelength of 550 nm. And these TFTs have an Ion/Ioff ratio of 1.8×108, a field effect mobility of 15.4 cm2/V·s, and a subthreshold swing of 186 mV/dec. The good electrical characteristics are retained even after bending with a curvature radius of 18 mm corresponding to a strain of 0.5% owing to mechanical durability of the transparent electrodes used in this study.
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Effects of Rapid Thermal Annealing on the Conduction of a-IGZO Films
Do Hoon Kim, Won Ju Choa
J Electr Electron Mater 2016;29(1):11-16.   Published online January 1, 2016
The conduction behavior and electron concentration change in a-IGZO thin-films according to the RTA (rapid thermal annealing) were studied. The electrical characteristics of TFTs (thin-film-transistors) annealed by different temperatures were measured. The sheet resistance, electron concentration, and oxygen vacancy of a-IGZO film were measured by the four-point-probe-measurement, hall-effect-measurement, and XPS analysis. The RTA process increased the driving current of IGZO TFTs but the VTH shifted to the negative direction at the same time. When the RTA temperature is higher than 250℃, the leakage current at off-state increased significantly. This is attributed to the increase of oxygen vacancy resulting in the increase of electron concentration. We demonstrate that the RTA is a promising process to adjust the VTH of TFT because the RTA process can easily modify the electron concentration and control the conductivity of IGZO film with short process time.
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Thin Films and Sensors : Regular Paper ; Structural, Optical, and Electrical Properties of IGZO Thin Film Sputtered with Various RF Powers
Changhyun Jin, Hongbae Kim
J Electr Electron Mater 2015;28(10):620-624.   Published online October 1, 2015
We have studied structural, optical and electrical properties of In-Ga-doped ZnO (IGZO) thin films. The IGZO thin films were deposited on the corning 1737 glass by RF magnetron sputtering method. The RF power in sputtering process was varied as 30, 50, 70, and 90 W respectively. All of the IGZO thin films transmittance in the visible range (400 nm ~ 800 nm) was above 83%. XRD analysis showed the IGZO thin films amorphous structure of the thin films without any peak. And also IGZO thin film have low resistivity (1.99×10-3 Ωcm), high carrier concentration (6.4×1020 cm-3), and mobility (10.3 cm2V-1s-1). By the studies we found that IGZO transparent thin film can be used as optoelectronic material and introduced application possibility for future electronic devices.
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Thin Films and Sensors : Regular Paper ; Change in the Energy Band Gap and Transmittance IGZO, ZnO, AZO OMO Structure According to Ag Thickness
Seung Min Lee, Hong Bae Kim, Sang Yeol Lee
J Electr Electron Mater 2015;28(3):185-190.   Published online March 1, 2015
In this study, we fabricated the indium gallium zinc oxide (IGZO), zinc oxide (ZnO), aluminum zincoxide (AZO). oxide and silver are deposited by magnetron sputtering and thermal evaporator, respectively transparency and energy band gap were changed by the thickness of silver layer. To fabricate metal oxide metal(OMO) structure, IGZO sputtered on a corning 1,737 glass substrate was used as bottom oxide material and then silver was evaporated on the IGZO layer, finally IGZO was sputtered on the silver layer we get the final OMO structure. The radio-frequency power of the target was fixed at 30 W. The chamber pressure was set to 6.0×10-3Torr, and the gas ratio of Ar was fixed at 25 sccm. The silver thickness are varied from 3 to 15 nm. The OMO thin films was analyzed using XRD. XRD shows broad peak which clearly indicates amorphous phase. ZnO, AZO,OMO show the peak [002] direction at 34°. This indicate that ZnO, AZO OMO structure show the crystalline peak. Average transmittance of visible region was over 75%, while that of infrared region was under 20%. Energy band gap of OMO layer was increased with increasing thickness of Ag layer. As a result total transmittance was decreased.
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We have investigated the effect of electrical properties of amorphous InGaZnO thin filmtransistors (a-IGZO TFTs) by post thermal annealing in O2 ambient.The post-annealed in O2 ambienta-IGZOTFT is found to be more stable to be used for oxide-based TFT devices, and has betterperformance, such as the on/off current ratios, sub-threshold voltage gate swing, and, as well asreasonable threshold voltage, than others do. The interface trap density is controlled to achieve theoptimum value of TFT transfer and output characteristics. The device performance is significantlyaffected by adjusting the annealing condition. This effect is closely related with the modulation annealingmethod by reducing the localized trapping carriers and defect centers at the interface or in the channellayer.
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Characteristics of IGZO/Ag/IGZO Multilayer Thin Films Depending On Ag Thickness
Ya Jun Zhang, Hong Bea Kim, Sang Yeol Lee
J Electr Electron Mater 2013;26(7):510-514.   Published online July 1, 2013
In order to prevent heat loss that occurs through the glass, low-emissivity (Low-E) coating methods with good insulating properties and high transmittance were used. lnGaZnO/Ag/InGaZnO (IGZO/Ag/IGZO) multilaver thin films have been deposited on XG glass substrate by HF magnetron sputtering. Depending on the different thickness of Ag in multilayer films, the structural and optical properties of Low-E multilayer films were analyzed. By XRI) analysis results, the multilayer thin films were observed to be amorphous structure regardless of Ag thickness. According to the AFM results, surface morphology of the multilayer films was observed and compared. Using UV-VIS spectroscopy, low emissivity propertty has been observed clearly with the transmittance of higher than 85% at visible range and lower than 30 at ll range.
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Energy Materials : Regular Paper ; Structural and Optical Properties of Multilayer Films of IGZO / Ag / IGZO for Low Emissivity Applications
Sang Yeol Lee, Hong Rae Wang, Hong Bae Kim
J Electr Electron Mater 2013;26(4):321-324.   Published online April 1, 2013
In this study, The RF magnetron sputter and evaporator was on glass substrates 30 mm × 30 mm OMO multilayer thin film structure is applied to the low-e. Structural and optical properties, a thin film was produced, the variable was placed into a variable deposition time of the oxide layer. According to the XRD measurement results there is no peak that satisfies the Bragg`s law (2dsinθ= nλ) which confirmed that it is an amorphous structure. RMS value of the results of the AFM measurement, has a roughness of less than 2 nm. transmittance measurements results, visible light region an average 80%, IR region 40% showed.
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Thin Films and Sensors : The Properties of ZnO:Ga,In(IGZO) Thin Films Prepared by RF Magnetron Sputtering
Hyoung Min Kim, Tae Young Ma, Ki Cheol Park
J Electr Electron Mater 2013;26(1):56-63.   Published online January 1, 2013
IGZO thin films have been prepared by RF magnetron sputtering. The structural, electrical and optical properties of the IGZO thin films have been investigated as a function of deposition condition. XRD analysis of IGZO thin films showed a typical crystallographic orientation with c-axis perpendicular regardless of deposition conditions. The carrier mobility, carrier concentration and resistivity of the IGZO films sputtered at 200 W, 1mTorr and 300℃ were 28.5 cm2/V·sec, 2.6×1020 cm3, 8.8×10-4 Ω·cm respectively. The optical transmittance were higher than 80% at visible region regardless of the deposition conditions under the experiments above, and specifically higher than 90% at wave length over 500 nm. The absorption edge was shifted to shorter wavelength with increase of carrier concentration.
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Thin Films and Sensors : Effects of Doping Concentration on the Properties of Ga-doped ZnO Thin Films Prepared by RF Magnetron Sputtering
Ki Cheol Park, Hyoung Min Kim, Dae Young Ma
J Electr Electron Mater 2012;25(12):984-989.   Published online December 1, 2012
We have investigated the structural, electrical and optical properties of Ga-doped ZnO (GZO) thin films prepared by RF magnetron sputtering with laboratory-made ZnO targets containing 1, 3, 5, 7 wt% of Ga2O3 powder as a doping source. The GZO thin films show the typical crystallographic orientation with c-axis regardless of Ga2O3 content in the targets. The 3,000 Å thick GZO thin films with the lowest resistivity of 7×10-4 Ω·cm are obtained by using the GZO (Ga2O3= 5 wt%) target. Optical transmittance of all films shows higher than 80% at the visible region. The optical energy band gap for GZO films increases as the carrier concentration (ne) in the film increases.
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A Study on Electrical, Optical Properties of GZO Thin Film with Target Crystalline
Kyu Ho Lee, Kyung Hwan Kim
J Electr Electron Mater 2012;25(2):114-120.   Published online February 1, 2012
In this research, we prepared Ga doped zinc oxide(ZnO:Ga, GZO) targets each difference sintering temperature 700℃, 800℃, and doping rate 1 wt.%, 2 wt.%, 3 wt.%. The characteristics of thin film on glass substrates which deposited by facing target sputtering in pure Ar atmosphere are reported. Ga doped zinc oxide film is attracted material through low resistivity, high transmittance, etc. When prepared target powder`s structure was investigated by scanning electron microscope, densification and coarsening by driving force was observed. For each ZnO:Ga films with a Ga2O3 content of 3 wt.% at input power of 45 W, the lowest resistivity of 9.967×10(-4) Ω·cm (700℃) and 9.846×10(-4) Ω ·cm (800℃) was obtained. the carrier concentration and mobility were 4.09 × 10(20) cm-3(700℃), 4.12×10(20) cm-3(800℃) and 15.31 cm2/V·s(700℃), 12.51 cm2/V·s(800℃), respectively. And except 1 wt.% Ga doped ZnO thin film, average transmittance of these samples in the range 350-800 nm was over 80%.
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Deposition Temperature and Annealing Temperature Dependent Structural and Electrical Properties of Ga-doped ZnO on SiC
Jung Ho Lee, Sang Mo Koo
J Electr Electron Mater 2012;25(2):121-124.   Published online February 1, 2012
The characteristics of Ga-doped zinc oxide (GZO) thin films deposited at different deposition temperatures (TS∼250 to 550℃) on 4H-SiC have been investigated. Structural and electrical properties of GZO thin film on n-type 4H-SiC(0001) were investigated by using x-ray diffraction(XRD), atomic force microscopy(AFM), Hall effect measurement, barrier height from I-V curve and Auger electron spectroscopy(AES). XRD 2 θ scan shows GZO thin film has preferential orientation with c-axis perpendicular to SiC substrate surface. The lowest resistivity (∼1.9×10-4 Ωcm) was observed for the GZO thin film deposited at 400℃. As deposition temperature increases, barrier height between GZO and SiC was increased. Whereas, resistivity of GZO thin films as well as barrier height between GZO and SiC were increased after annealing process in air atmosphere. It has been found that the c-axis oriented crystalline quality as well as the relative amount of activated Ga3+ ions and oxygen vacancy may affect the electrical properties of GZO films on SiC.
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Effect of SiO2 Buffer Layer Thickness on the Device Reliability of the Amorphous InGaZnO Pseudo-MOS Field Effect Transistor
Se Won Lee, Yeong Hyeon Hwang, Won Ju Cho
J Electr Electron Mater 2012;25(1):24-28.   Published online January 1, 2012
In this study, we fabricated an amorphous InGaZnO pseudo-MOS transistor (a-IGZO Ψ -MOSFET) with a stacked Si3N4/SiO2 (NO) gate dielectric and evaluated reliability of the devices with various thicknesses of a SiO2 buffer layer. The roles of a SiO2 buffer layer are improving the interface states and preventing degradation caused by the injection of photo-created holes because of a small valance band offset of amorphous IGZO and Si3N4. Meanwhile, excellent electrical properties were obtained for a device with 10-nm-thick SiO2 buffer layer of a NO stacked dielectric. The threshold voltage shift of a device, however, was drastically increased because of its thin SiO2 buffer layer which highlighted bias and light-induced hole trapping into the Si3N4 layer. As a results, the pseudo-MOS transistor with a 20-nm-thick SiO2 buffer layer exhibited improved electrical characteristics and device reliability; field effective mobility(μFE) of 12.3 cm2/V·s, subthreshold slope (SS) of 148 mV/dec, trap density (Nt) of 4.52× 1011 cm-2, negative bias illumination stress (NBIS) ΔVth of 1.23 V, and negative bias temperature illumination stress (NBTIS) ΔVth of 2.06 V.
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Regular Paper : Semiconductor ; Interface State Control of Amorphous InGaZnO Thin Film Transistor by Surface Treatment of Gate Insulator
Bo Sul Kim, Do Hyung Kim, Sang Yeol Lee
J Electr Electron Mater 2011;24(9):693-696.   Published online September 1, 2011
Recently, amorphous oxide semiconductors (AOSs) based thin-film transistors (TFTs) have received considerable attention for application in the next generation displays industry. The research trends of AOSs based TFTs investigation have focused on the high device performance. The electrical properties of the TFTs are influenced by trap density. In particular, the threshold voltage (Vth) and subthreshold swing (SS) essentially depend on the semiconductor/gate-insulator interface trap. In this article, we investigated the effects of Ar plasma-treated SiO2 insulator on the interfacial property and the device performances of amorphous indium gallium zinc oxide (a-IGZO) TFTs. We report on the improvement in interfacial characteristics between a-IGZO channel layer and gate insulator depending on Ar power in plasma process, since the change of treatment power could result in different plasma damage on the interface.
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Ga doped ZnO (GZO)/Cu bi-layer films were deposited with RF and DC magnetron sputtering on glass substrate and then the effect of post deposition annealing temperature on the structural, optical and electrical properties of the films was investigated. The post deposition annealing process was conducted for 30 minutes in gas pressure of 1×10-3 Torr and the annealing temperatures were 150 and 300℃. With increasing annealing temperature, GZO/Cu films showed an increment in the prefer orientation of ZnO (002) diffraction peak in the XRD pattern and the optical transmittance in a visible wave region was also increased, while the electrical sheet resistance was decreased. The GZO/Cu films annealed at 300℃ showed the highest optical transmittance of 70% and also showed the lowest electrical resistance of 85 Ω/□ in this study.
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Comparison of Stability on the Nano-crystalline Embedded InGaZnO and Amorphous InGaZnO Oxide Thin-film Transistors
Hyun Soo Shin, Byung Du Ahn, Yoo Seung Rim, Hyun Jae Kim
J Electr Electron Mater 2011;24(6):473-479.   Published online June 1, 2011
In this paper, we have compared amorphous InGaZnO (a-IGZO) thin-film transistor (TFT) with the nano-crystalline embedded-IGZO (Nc-embedded-IGZO) TFT fabricated by solid-phase crystallization (SPC) technique. The field effect mobility (μFE) of Nc-embedded-IGZO TFT was 2.37 cm2/Vs and the subthreshold slope (S-factor) was 0.83 V/decade, which showed lower performance than those of a-IGZO TFT (μFE of a-IGZO was 9.67 cm2/Vs and S-factor was 0.19 V/decade). This results originated from generation of oxygen vacancies in oxide semiconductor and interface between gate insulator and semiconductor due to high temperature annealing process. However, the threshold voltage shift (△V(TH)) of Nc-embedded-IGZO TFT was 0.5 V, which showed 1 V less shift than that of a-IGZO TFT under constant current stress during 10(5) s. This was because there were additionally less increase of interface trap charges in Nc-embedded-IGZO TFT than a-IGZO TFT.
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Regular Paper : Thickness Dependence of GZO Gas Sensing Films Deposited on LTCC Substrates
Hyun Suk Hwang
J Electr Electron Mater 2011;24(3):215-218.   Published online March 1, 2011
A novel design of gas sensor using Ga-doped ZnO (GZO) thin films which are deposited on low temperature co-fired ceramic (LTCC) substrates is presented. The LTCC substrates with thickness of 400 μm are fabricated by laminating 12 green tapes which consist of alumina and glass particle in an organic binder. The GZO thin films with different thickness are deposited on LTCC substrates, by RF magnetron sputtering method. The microstructure and sensing properties of GZO gas sensing films are analyzed as a function of the film thickness. The films are well crystallized in the hexagonal (wurzite) structure with increasing thickness. The maximum sensitivity of 3.49 is obtained at 100 nm film thickness and the fastest 90% response time of 27.2 sec is obtained at 50 nm film thickness for the operating temperature of 400oC to the NO2 gas.
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Regular Paper : Properties of Transparent Conductive IGZO Thin Films Deposited at Various Substrate Temperatures
Mi Sun Kim, Dong Young Kim, Sung Bo Seo, Kang Bae, Sun Young Sohn, Hwa Min Kim
J Electr Electron Mater 2010;23(12):961-965.   Published online December 1, 2010
In this study, we investigated the optical, electrical, and structural properties of the IGZO(In2O3:Ga2O3:ZnO=1:9:90 wt.%) thin films prepared by RF-magnetron sputtering system under various substrate temperatures. All of the IGZO thin films shows an average transmittance of over the 80% in visible range. Most of all, deposited IGZO thin film at 100 ˚C substrate temperature have ZnO (002) of main growth peak and 17.02 nm of increased grains. And also IGZO thin film have low resistivity(1.35×10(-3) Ω·cm), high carrier concentration(6.62X10(20) cm-3) and mobility(80.1 cm2/Vsec). IGZO thin film have 2.08 mV at surface potential of electric force microscopy(EFM). We suggest that pre-annealing at 100 ˚C can be applied for improving optical, electrical and structural properties.
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Regular Paper : Effect of Ga Dopants on Electrical and Optical Characteristics of ZnO Thin Films
Jun Sik Kim, Gun Eik Jang
J Electr Electron Mater 2010;23(9):685-690.   Published online September 1, 2010
ZnO with the wide band gap near 3.37 eV is typically an n-type semiconductor in which deviation from stoichiometry is electrically active. It was known that the films with a resistivity of the order of 10-4 Ωcm is not easy to obtain. In order to improve electrical characteristic of ZnO, we added 1, 3, 5 wt% Ga element in ZnO. The Ga-doped ZnO (GZO) was grown on a glass substrate by radio frequency (RF) magnetron sputtering at the temperature range from 100 to 500℃. X-ray diffraction (XRD) patterns of GZO films showed preferable crystal orientation of (002) plane. The lowest resistivity of the GZO films was 8.9×10-4 Ωcm. GZO films significantly influenced by the working temperature. The average transmittance of the films was over 80% in the visible ranges.
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Study on the Electrical Properties of a-IGZO TFTs Depending on Processing Parameters
Eu Gene Chong, Kyoung Chol Jo, Seung Han Kim, Sang Yeol Lee
J Electr Electron Mater 2010;23(5):349-352.   Published online May 1, 2010
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The Characteristic Changes of Amorphous-InGaZnO Thin Film according to RF Power
Sang Hun Kim, Yong Heon Park, Hong Bae Kim
J Electr Electron Mater 2010;23(4):293-297.   Published online April 1, 2010
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