Frequency-Stable Ionic-Type Hybrid Gate Dielectrics for High Mobility Solution-Processed Metal-Oxide Thin-Film Transistors

Heo, Jae Sang; Choi, Seungbeom; Jo, Jeong Wan; Kang, Jingu; Park, Ho Hyun; Kim, Yong Hoon; Park, Sung Kyu

doi:10.3390/ma10060612

Cited by 9 publications

(18 citation statements)

References 36 publications

(34 reference statements)

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“…The EDL capacitor is formed by electrostatic accumulation, whereas the pseudo‐capacitor is formed by the Faradaic charge‐transfer process, which is an electrochemical process (Figure d) . With these materials as capacitors, the C ‐ f diagram can be displayed in three cases (Figure e): 1) a normal dielectric only containing bulk capacitance (bottom); 2) an electrolyte‐like dielectric containing EDL capacitance and bulk capacitance (middle); 3) an electrolyte‐like dielectric layer containing pseudocapacitance, EDL capacitance and bulk capacitance (top) . In particular, oxide materials (e.g., SiO x and AlO x ) fabricated by the solution method can be called ionic conductors or solid‐state electrolytes, which is defined as a solid material conducting mainly by ionic migration but acting as an insulator for electrons .…”

Section: Ideal and Nonideal Ofetsmentioning

confidence: 99%

Understanding, Optimizing, and Utilizing Nonideal Transistors Based on Organic or Organic Hybrid Semiconductors

Yang

Dai

et al. 2019

Adv Funct Materials

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Many advanced materials have been developed for organic field-effect transistors (OFETs) or thin-film transistors (TFTs) based on organic and organic hybrid materials. However, although many new OFETs exhibit superior characteristic parameters (such as high mobility), most of them show nonideal performances that have strongly limited progress in the design of molecules, the understanding of transport mechanisms, and the circuit applications of OFETs. In this review, the device physics of ideal and nonideal OFETs is discussed first to understand the factors that limit effective mobility in semiconducting channels, distort the potential distribution, or reduce the drift electric field. Then, recent advances in optimizing the material combinations, device structures, and fabrications of OFETs toward ideal transistors are discussed. Based on the good control of materials and interfaces, some new and novel concepts to utilize the nonideal properties of OFETs to build low-power circuits and integrated sensors are also discussed.

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Section: Ideal and Nonideal Ofetsmentioning

confidence: 99%

Understanding, Optimizing, and Utilizing Nonideal Transistors Based on Organic or Organic Hybrid Semiconductors

Yang

Dai

et al. 2019

Adv Funct Materials

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“…It is acknowledged that electrical double layer formed in the solution-processed metal oxide gate dielectrics will lead to higher capacitance [41,42], as shown in the inset of Fig. 6b.…”

Section: Thin Film and Device Characterizationmentioning

confidence: 99%

Solution-processed amorphous gallium-tin oxide thin film for low-voltage, high-performance transistors

Ren

Yang

et al. 2018

Sci. China Mater.

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Gallium-tin oxide (GTO) semiconductor thin films were prepared by spin-coating with 2-methoxyethanol as the solvent. Their crystal structures, optical transparency, chemical states and surface morphologies, along with the electrical properties, were dependent on Ga contents and annealing temperatures. The optimized GTO channel layer was applied in the high-k Al 2 O 3 thin film transistor (TFT) with a low operation voltage of 2 V, a maximum field-effect mobility of 69 cm 2 V −1 s −1 , a subthreshold swing (SS) of 76 mV dec −1 , a threshold voltage of 0.67 V and an on-off current ratio of 1.8×10 7. The solution-processed amorphous-GTO-TFTs would promote the development of low-consumption, low-cost and high performance In-free TFT devices.

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“…13 Heo et al attributed the mobility enhancement to electric double layer (EDL) formation at the solutionprocessed AlO x /InO x interface. 14 In most cases, large capacitance induced by EDL can lead to low operating voltage. However, numerical simulations have revealed that, once the…”

mentioning

confidence: 99%

“…The strong dependence of capacitance on frequency and voltage suggests the possible formation of pseudocapacitance in addition to the EDL. 19 Usually, solution-processed gate dielectrics fabricated at low temperatures are not dense and feature unintentional defects causing cations and anions, 14 which can be regarded as solid-state electrolytes. 20−22 With the EDL effect, charge accumulation is achieved electrostatically at the gate/electrolyte and electrolyte/semiconductor interfaces, and the EDL capacitance C EDL arises from the surface-charge density.…”

mentioning

confidence: 99%

“…However, for some TFTs with high- k gate dielectrics, the mobility was not enhanced. , Zeumault et al proposed that donor-like traps in ZrO 2 are aligned at shallow energies with respect to the transport band of ZnO and provide more carriers in the ZnO channel by charge migration at the insulator/semiconductor interface, resulting in high mobility . Heo et al attributed the mobility enhancement to electric double layer (EDL) formation at the solution-processed AlO x /InO x interface . In most cases, large capacitance induced by EDL can lead to low operating voltage.…”

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confidence: 99%

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Evidence for Pseudocapacitance and Faradaic Charge Transfer in High-Mobility Thin-Film Transistors with Solution-Processed Oxide Dielectrics

Liang

Liu

Cai

et al. 2020

J. Phys. Chem. Lett.

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In developing low-power electronics, low-voltage transistors have been intensively investigated. One of the most important findings is that some high-k oxide gate dielectrics can lead to remarkable enhancement of apparent mobility in thin-film transistors (TFTs), which is not clearly understood. Here, we investigate InO x TFTs with solution-processed AlO x dielectrics. At very low frequencies (<1 Hz), the AlO x films feature strong voltage-dependent capacitance. Also, cyclic voltammograms show clear features of surface-controlled Faradaic charge transfer. The two independent experiments both point to the formation of pseudocapacitance, which is similar to the mechanism behind some supercapacitors. A physical model including charge transfer is established to describe ion distribution. The charge transfer is probably related to residual hydrogens, as revealed by secondary-ion mass spectroscopy. The results provide direct evidence of the formation of pseudocapacitance in TFTs with high apparent mobilities and advance the understanding of mechanisms, measurements, and applications of such TFTs for low-power electronics.M etal-oxide thin-film transistors (TFTs) have attracted significant attention for applications in the area of active-matrix devices such as high-resolution displays with organic light-emitting diodes. 1−4 The advantages include largearea uniformity, high mobility, and compatibility in a flexible electronic device. To improve the performance of the metaloxide TFTs, high-k dielectrics have been used as gate insulator in metal-oxide TFTs such as Y 2 O 3 , Al 2 O 3 , ZrO 2 , and HfO 2 . 5−8 It is exciting to note that there are considerable reports that the solution-processed high-k gate dielectric induces remarkable enhancement of mobility, 9,10 with several to 10 times as compared with that in the cases with thermal silicon oxide gate. However, no consensus yet exists on how to explain this remarkable enhancement.Lee et al. attributed the mobility enhancement to the increased capacitance and carrier density using a high-k gate dielectric. 11 However, for some TFTs with high-k gate dielectrics, the mobility was not enhanced. 6,12 Zeumault et al. proposed that donor-like traps in ZrO 2 are aligned at shallow energies with respect to the transport band of ZnO and provide more carriers in the ZnO channel by charge migration at the insulator/semiconductor interface, resulting in high mobility. 13 Heo et al. attributed the mobility enhancement to electric double layer (EDL) formation at the solutionprocessed AlO x /InO x interface. 14 In most cases, large capacitance induced by EDL can lead to low operating voltage. However, numerical simulations have revealed that, once the

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Frequency-Stable Ionic-Type Hybrid Gate Dielectrics for High Mobility Solution-Processed Metal-Oxide Thin-Film Transistors

Cited by 9 publications

References 36 publications

Understanding, Optimizing, and Utilizing Nonideal Transistors Based on Organic or Organic Hybrid Semiconductors

Understanding, Optimizing, and Utilizing Nonideal Transistors Based on Organic or Organic Hybrid Semiconductors

Solution-processed amorphous gallium-tin oxide thin film for low-voltage, high-performance transistors

Evidence for Pseudocapacitance and Faradaic Charge Transfer in High-Mobility Thin-Film Transistors with Solution-Processed Oxide Dielectrics

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