A Study on the Degradation of In-Ga–Zn-O Thin-Film Transistors Under Current Stress by Local Variations in Density of States and Trapped Charge Distribution

Kim, Hyeongjung; Jo, Chunhyung; Kim, Hyunsuk; Choi, Sung-Jin; Kim, Dong Myong; Park, Jozeph; Kim, Dae Hwan

doi:10.1109/led.2015.2438333

Cited by 12 publications

(6 citation statements)

References 14 publications

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“…Donor-like states originate from the impact ionization of oxygen vacancies in the IGZO layer (Vo + e − → Vo 2+ + 3e − ). These positively charged states result in a negative V T shift [ 13 , 24 , 25 , 26 , 27 ]. This mechanism is dominant near the drain side because the lateral electric field is higher than the source side.…”

Section: Resultsmentioning

confidence: 99%

Analysis of Threshold Voltage Shift for Full VGS/VDS/Oxygen-Content Span under Positive Bias Stress in Bottom-Gate Amorphous InGaZnO Thin-Film Transistors

et al. 2021

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In this study, we analyzed the threshold voltage shift characteristics of bottom-gate amorphous indium-gallium-zinc-oxide (IGZO) thin-film transistors (TFTs) under a wide range of positive stress voltages. We investigated four mechanisms: electron trapping at the gate insulator layer by a vertical electric field, electron trapping at the drain-side GI layer by hot-carrier injection, hole trapping at the source-side etch-stop layer by impact ionization, and donor-like state creation in the drain-side IGZO layer by a lateral electric field. To accurately analyze each mechanism, the local threshold voltages of the source and drain sides were measured by forward and reverse read-out. By using contour maps of the threshold voltage shift, we investigated which mechanism was dominant in various gate and drain stress voltage pairs. In addition, we investigated the effect of the oxygen content of the IGZO layer on the positive stress-induced threshold voltage shift. For oxygen-rich devices and oxygen-poor devices, the threshold voltage shift as well as the change in the density of states were analyzed.

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Section: Resultsmentioning

confidence: 99%

Analysis of Threshold Voltage Shift for Full VGS/VDS/Oxygen-Content Span under Positive Bias Stress in Bottom-Gate Amorphous InGaZnO Thin-Film Transistors

et al. 2021

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“…When the gate bias is applied to the TFT, the HfO 2 gate insulator will provide a strong electric field near the IGZO/HfO 2 interface to bend the Fermi level in the deep of the band gap. The energy level of the neutral oxygen vacancies (V O ), which is higher than the Fermi level, will be ionized (V O ++ ) and two electrons will be contributed to the IGZO film because the highest electron energy level in the IGZO band gap cannot reach the energy level of V O [ 10 , 18 ]. Therefore, the extra free electrons generated during the forward sweep of the gate bias will cause the negative V th shift in the reverse sweep of the gate bias.…”

Section: Resultsmentioning

confidence: 99%

“…For the a-IGZO TFT without treatment, the device suffers from a more serious negative V th shift and a S.S. degradation, as shown in Figure 6 a,b, which are mainly due to the moisture from the ambient atmosphere absorbed onto the IGZO surface. The absorbed moisture will bond to the metal element in IGZO to form metal-hydroxide (M-OH) bonds, which act as donor-like states to provide extra electrons, but also increase the density of state within the IGZO film [ 18 ]. Thus, the absorbed moisture will cause a negative V th shift and an S.S. degradation.…”

Section: Resultsmentioning

confidence: 99%

“…However, the electrical stability of the a-IGZO TFT with a high-k gate dielectric layer is one of the critical issues, especially under the positive-gate bias stress (PGBS) [ 10 ]. The threshold voltage (V th ) is abnormally shifted in the negative direction, which is opposite to the a-IGZO TFT with a SiO 2 gate insulator [ 18 , 19 ]. This is due to the electron density generated by the density of states (DOS) near the dielectric/channel layer interface or from absorbed moisture from the air.…”

Section: Introductionmentioning

confidence: 99%

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Electrical Performance and Reliability Improvement of Amorphous-Indium-Gallium-Zinc-Oxide Thin-Film Transistors with HfO2 Gate Dielectrics by CF4 Plasma Treatment

Fan

Tseng

2018

Materials

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In this work, amorphous indium-gallium-zinc oxide thin-film transistors (a-IGZO TFTs) with a HfO2 gate insulator and CF4 plasma treatment was demonstrated for the first time. Through the plasma treatment, both the electrical performance and reliability of the a-IGZO TFT with HfO2 gate dielectric were improved. The carrier mobility significantly increased by 80.8%, from 30.2 cm2/V∙s (without treatment) to 54.6 cm2/V∙s (with CF4 plasma treatment), which is due to the incorporated fluorine not only providing an extra electron to the IGZO, but also passivating the interface trap density. In addition, the reliability of the a-IGZO TFT with HfO2 gate dielectric has also been improved by the CF4 plasma treatment. By applying the CF4 plasma treatment to the a-IGZO TFT, the hysteresis effect of the device has been improved and the device’s immunity against moisture from the ambient atmosphere has been enhanced. It is believed that the CF4 plasma treatment not only significantly improves the electrical performance of a-IGZO TFT with HfO2 gate dielectric, but also enhances the device’s reliability.

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“…Long term period ~10 1 sec. static stress conditions and local VT variation inside the channel [5]. We found the physical mechanism of thermally activated and field-enhanced diffusion of dopants, which is understood as a change in RSD in terms of device degradation.…”

Section: Gate Driver Unitmentioning

confidence: 90%

P‐30: Thermally Activated and Field‐Enhanced Diffusion of Dopants in a‐InGaZnO TFTs Under Circuit Operations and Correlation to Device Stabilities

Ryoo

Yang

Lee

et al. 2022

Symp Digest of Tech Papers

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The spatial distribution of the donor dopant and the source‐drain resistance (RSD) in oxide Thin Film Transistor (TFT) for display backplane is usually considered to be determined by the device structure and the process. This work shows that the dopant concentration of lateral distribution of thermal equilibrium carrier concentration n0(y) may vary dynamically depending on the operation conditions during circuit operation and thermally‐activated and field‐enhanced diffusion of dopants in InGaZnO (IGZO) was found as a physical cause. In actual Organic Light‐Emitting Diode (OLED) backplane circuit operation, the reliability degradation conditions of IGZO TFTs were summarized into three conditions: Negative Bias Temperature Stress (NBTS), Constant Voltage Stress (CVS), and Drain‐to‐Source Voltage (VDS)‐sweep, and as a result of analyzing TFT device reliability, dopant diffusion occurred as the temperature increased, and the lateral field increased, resulting in RSD increase and channel resistance decrease. This causes degradation of device characteristics accumulated during circuit operation and shows various degradation patterns. It is connected to the existing Positive Bias Stress (PBS) and Negative Bias Stress (NBS) degradation mechanisms and other hot carrier degradation and self‐heating. In particular, it has been reported that dopant diffusion and source‐drain series resistance (RSD) change occur under high VGS, high VDS, and short channel conditions, resulting in permanent failure of the IGZO TFT channel by forming positive feedback.

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A Study on the Degradation of In-Ga–Zn-O Thin-Film Transistors Under Current Stress by Local Variations in Density of States and Trapped Charge Distribution

Cited by 12 publications

References 14 publications

Analysis of Threshold Voltage Shift for Full VGS/VDS/Oxygen-Content Span under Positive Bias Stress in Bottom-Gate Amorphous InGaZnO Thin-Film Transistors

Analysis of Threshold Voltage Shift for Full VGS/VDS/Oxygen-Content Span under Positive Bias Stress in Bottom-Gate Amorphous InGaZnO Thin-Film Transistors

Electrical Performance and Reliability Improvement of Amorphous-Indium-Gallium-Zinc-Oxide Thin-Film Transistors with HfO2 Gate Dielectrics by CF4 Plasma Treatment

P‐30: Thermally Activated and Field‐Enhanced Diffusion of Dopants in a‐InGaZnO TFTs Under Circuit Operations and Correlation to Device Stabilities

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