Reduced Mechanical Strain in Bendable a-IGZO TFTs Under Dual-Gate Driving

Billah, Mohammad Masum; Han, Ji-Ung; Hasan, Mehedi; Jang, Jin

doi:10.1109/led.2018.2825454

Cited by 24 publications

(21 citation statements)

References 17 publications

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“…The "k" is the fitting constant and was found to be smaller for the in-folding (k ¼ 0.06) than that of out-folding (k ¼ 0.08), and both k values were found to be smaller than the reported oxide semiconductor TFTs. [36] Gleskova et al reported mechanical strain-induced failure analysis such as crack formation in silicon TFTs. [37] They explained that tensile strain-induced electrical degradation occurs mainly due to elastically deforming until crack formation.…”

Section: Resultsmentioning

confidence: 99%

Excellent Mechanical Durability of In‐Folding Stress of Poly‐Si Thin‐Film Transistor on Plastic Substrate Compared with Out‐Folding: Generation of Gate Leakage Currents in Flexible Poly‐Si Thin‐Film Transistor by Out‐Folding and Bias‐Temperature Stress

et al. 2020

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The effect of electro‐thermal stress on the electrical performance of flexible, low‐temperature polysilicon (LTPS) thin‐film transistors (TFTs) after mechanical‐folding stress aiming to improve the reliability of foldable display backplanes is studied (IG). Herein, for the first time, the significant increase of gate leakage currents upon the negative bias temperature stress (NBTS) or positive bias temperature stress (PBTS) after the out‐folding test on excimer laser annealing (ELA) TFTs is reported. Out‐folding stress increases the drain current, shifts the threshold voltage (ΔVTH) by 2.4 V, and increases the subthreshold swing without affecting the (IG). However, the ΔVTH is 1.8 V upon NBTS, and the negative ΔVTH is −4.7 V upon PBTS after out‐folding stress along with a drastic increase in IG. A thermal annealing at 250 °C for 10 h for the electro‐thermal stressed TFTs after out‐folding is performed, and initial electrical characteristics recovery is achieved; except the abruptly increased IG. These results are correlated with charge trapping at the damaged grain boundary and (GI). A model with moisture/water molecule diffusion through the nanocracks generated by out‐folding is proposed. The ionized charges (H+, OH−) captured at the nanocrack‐induced trap sites in poly‐Si and GI appear to be the origin of abnormal ΔVTH and IG.

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Section: Resultsmentioning

confidence: 99%

Excellent Mechanical Durability of In‐Folding Stress of Poly‐Si Thin‐Film Transistor on Plastic Substrate Compared with Out‐Folding: Generation of Gate Leakage Currents in Flexible Poly‐Si Thin‐Film Transistor by Out‐Folding and Bias‐Temperature Stress

et al. 2020

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“…9(c)-(d), we performed TCAD simulation to check the role of CNT layer inside PI layers once external mechanical strain is incident on flexible a-IGZO TFTs. We created bendable structures with single CNT and CNT+GO with CNT buried layers while considering an arbitrary bending radius (R) using Devedit device simulator of Silvaco TCAD [24]. For mechanical strain (ε) distribution, we performed victory 3D stress distribution module and the mechanical properties of different TFT and substrate layers are listed in TABLE 1 [24].…”

Section: Resultsmentioning

confidence: 99%

“…We created bendable structures with single CNT and CNT+GO with CNT buried layers while considering an arbitrary bending radius (R) using Devedit device simulator of Silvaco TCAD [24]. For mechanical strain (ε) distribution, we performed victory 3D stress distribution module and the mechanical properties of different TFT and substrate layers are listed in TABLE 1 [24]. From TCAD based strain distribution, it is clearly observed that the flexible TFT on 7 μm thick PI substrate with one CNT buried layer exhibits an applied tensile strain of about 0.70 % on a-IGZO channel, whereas, the applied tensile strain of about 0.40% is observed for the structure with CNT+GO and CNT layer inside PI substrate (2x time larger strain), suggesting that CNT layer might limits/absorb the applied strain and thus, less defect generation inside a-IGZO layer might occur with buried CNT inside PI as compared to conventional PI based flexible TFTs.…”

Section: Resultsmentioning

confidence: 99%

“…Interestingly, flexible TFTs on buried CNT based PI substrate show a robust electrical performance of only V Th = −0.3 V after the same amount stretching. threshold voltage after mechanical strain/stress are mainly explained by the change of interatomic distance, formation of trap sites, formation of defect states at GI/a-IGZO interface and/or bulk a-IGZO, due to applied external mechanical strain [18]- [24], [29]. In contrast, the robust electrical performance of the flexible oxide TFTs on buried CNT layer based PI substrate might be originated from the presence of buried CNT layer with higher Young's modulus in the middle of PI substrate that might limits the mechanical elongation of the a-IGZO layer.…”

Section: Methodsmentioning

confidence: 99%

“…Furthermore, the CNT+GO backbone also makes the PI wrinkle-free because the CNT+GO remains being attached to the back side of the PI after detachment [18]. Therefore, the mixture of carbon nanotube (CNT) and graphene oxide (GO) was used as a buffer for nonlaser detach [18]- [21], [23]- [24], [27]. The first PI layer was deposited by the spin-coating process at 2000 rpm for 60 s to achieve a thickness ∼3 μm on top of the CNT+GO layer.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Robust Oxide Thin-Film Transistors With Embedded CNT Buried Layer for Stretchable Electronics

Hasan

Billah

et al. 2019

IEEE J. Electron Devices Soc.

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We report the impact of carbon nanotube (CNT) buried layer in the middle of 7 μm polyimide (PI) substrate on the electrical performance of amorphous-indium-gallium-zinc-oxide (a-IGZO) thin-film transistors (TFTs) by repetitive mechanical stretching. TFT arrays on 3 mm × 3 mm PI layers were attached on 40 μm polydimethylsiloxane (PDMS) substrate by double-sided PI tape. A negative threshold voltage shift (V Th (V)) of −3 V has been found under 70% mechanical stretching for the TFTs on the conventional PI substrate, whereas the TFTs with CNT layer inside PI substrate exhibited robust TFT performance. The fabricated oxide TFTs reported here with CNT inside PI substrate shows field effect mobility (μ FE) ∼ 14 cm 2 /V • s at pristine state, and changed <5% after repetitive mechanical stretching and bending which might be attributed from the strain absorbing CNT layer inside PI substrate using TCAD simulation.

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Control of Carrier Concentrations in AOSs and Application to Bulk‐Accumulation TFTs

Lee

Jang

2022

Amorphous Oxide Semiconductors

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Reduced Mechanical Strain in Bendable a-IGZO TFTs Under Dual-Gate Driving

Cited by 24 publications

References 17 publications

Excellent Mechanical Durability of In‐Folding Stress of Poly‐Si Thin‐Film Transistor on Plastic Substrate Compared with Out‐Folding: Generation of Gate Leakage Currents in Flexible Poly‐Si Thin‐Film Transistor by Out‐Folding and Bias‐Temperature Stress

Excellent Mechanical Durability of In‐Folding Stress of Poly‐Si Thin‐Film Transistor on Plastic Substrate Compared with Out‐Folding: Generation of Gate Leakage Currents in Flexible Poly‐Si Thin‐Film Transistor by Out‐Folding and Bias‐Temperature Stress

Robust Oxide Thin-Film Transistors With Embedded CNT Buried Layer for Stretchable Electronics

Control of Carrier Concentrations in AOSs and Application to Bulk‐Accumulation TFTs

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