Gate Capacitance‐Dependent Field‐Effect Mobility in Solution‐Processed Oxide Semiconductor Thin‐Film Transistors

Lee, Eungkyu; Ko, Jieun; Lim, Keon Hee; Kim, Kyongjun; Park, Si Yun; Myoung, Jae Min; Kim, Youn Sang

doi:10.1002/adfm.201400588

Cited by 88 publications

(63 citation statements)

References 33 publications

(94 reference statements)

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“…2 and SI Appendix, Fig. S13) (38). From these results, the SCS performance enhancement vs. spin-CS processing plausibly reflects more extensive M-O-M lattice densification and distortional relaxation, thereby reducing trap sites.…”

Section: Significancementioning

confidence: 84%

Spray-combustion synthesis: Efficient solution route to high-performance oxide transistors

Smith²,

Zhou

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

179

186

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Metal-oxide (MO) semiconductors have emerged as enabling materials for next generation thin-film electronics owing to their high carrier mobilities, even in the amorphous state, large-area uniformity, low cost, and optical transparency, which are applicable to flat-panel displays, flexible circuitry, and photovoltaic cells. Impressive progress in solution-processed MO electronics has been achieved using methodologies such as sol gel, deep-UV irradiation, preformed nanostructures, and combustion synthesis. Nevertheless, because of incomplete lattice condensation and film densification, high-quality solution-processed MO films having technologically relevant thicknesses achievable in a single step have yet to be shown. Here, we report a low-temperature, thickness-controlled coating process to create high-performance, solution-processed MO electronics: spray-combustion synthesis (SCS). We also report for the first time, to our knowledge, indium-gallium-zinc-oxide (IGZO) transistors having densification, nanoporosity, electron mobility, trap densities, bias stability, and film transport approaching those of sputtered films and compatible with conventional fabrication (FAB) operations. etal-oxide (MO) semiconductors, especially in amorphous phases, represent an appealing materials family for next generation electronics owing to their high carrier mobilities, good environmental/thermal stability, mechanical flexibility, and excellent optical transparency (1-3). MO films complement organic semiconductors (4, 5), carbon/oxide nanomaterials (6), and flexible silicon (7, 8) for enabling new technologies, such as flexible displays and printed sensors. For fabricating high-performance electronics with acceptable fidelity, conventional processes require capital-intensive physical/chemical vapor deposition techniques. Capitalizing on the solubility of MO precursors in common solvents, solution methods have been used to fabricate semiconducting MO layers for thin-film transistors (TFTs). However, the fabrication process and field-effect mobilities of these TFTs are not competitive with the corresponding vapor-deposited (e.g., sputtered) devices (9), and developing routes to solution-derived MO TFTs with technologically relevant thicknesses and performance comparable to state of the art vapor-deposited devices is a critical milestone for MO electronics evolution.Sol-gel techniques are used extensively for MO film growth, including films for high-performance TFTs (10-13). However, the required sol-gel condensation, densification, and impurity removal steps typically require >400-500°C processing temperatures, which are incompatible with inexpensive glasses and typical flexible plastic substrates (14). Progress toward significantly reducing the processing temperatures of sol gel-derived MO films has afforded excellent TFT mobilities; however, achieving both reproducible high-performance and stable device operation remains an unsolved issue for Ga-containing materials (15). Sol-gel on-a-chip for indium-zinc-oxide (3) and deep-UV ...

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Section: Significancementioning

confidence: 84%

Spray-combustion synthesis: Efficient solution route to high-performance oxide transistors

Smith²,

Zhou

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

179

186

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“…Although this effect is very reliably reproduced experimentally , its precise cause is only beginning to be understood. This lack of understanding has led to recent attempts to identify a physical origin .…”

Section: Introductionmentioning

confidence: 99%

Use of high-k encapsulation to improve mobility in trap-limited metal-oxide semiconductors

Zeumault

Subramanian

2017

Phys. Status Solidi B

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Low‐temperature spray‐deposited ZnO films are encapsulated by insulating Ga2O3 films and the resulting electronic properties of heterostructure films and transistors are analyzed and compared to un‐encapsulated ZnO as a function of processing temperature. An enhancement in Hall mobility and field‐effect mobility is observed similar to when high‐k dielectrics are used as gate‐dielectrics in transparent conductive oxide thin‐film transistors except without the presence of undesirable device behavior such as gate‐leakage and hysteresis. Based on a recently proposed theory consisting of electron donation from high‐k dielectrics, work function measurements show that conditions for electron transfer from Ga2O3 to ZnO can be met by optimally‐tuning the deposition temperature of the respective films resulting in an effective doping which is qualitatively similar to modulation doping. As a result, TFTs composed of ZnO/Ga2O3 heterostructures exhibit greatly improved switching characteristics and electron transport relative to the otherwise poor performance of low‐temperature processed ZnO achieved through a simple modification to TFT device structure.

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“…The increase of gate capacitance with high k dielectric may lower the activation energy of electron transition and lead to the filling of the tail state up to higher energy levels. Thus, the electron can easily jump to the transport bands in the percolation path, as demonstrated by the noticeably high mobility in our ZnO TFTs.…”

Section: Resultsmentioning

confidence: 75%

“…Materials with high k and good film forming ability are needed to increase the area normalized gate capacitance and to reduce the leakage current density. Numerous transparent and high k metal oxide dielectrics, such as AlO x , HfO 2 , ZrO x , AlO x , Y 2 O 3 , HfLaO x , and A1 2x‐1 Ti x O y , have been implemented into ZnO TFTs by solution processes. All of them could achieve excellent electron transport characteristics with mobility in a range of 0.18–45.5 cm 2 V −1 s −1 under an operating voltage of <10 V. Table shows a comparison of the results reported by ZnO TFTs with solution‐processed high k oxide dielectric.…”

Section: Introductionmentioning

confidence: 99%

Fully Solution‐Processed Low‐Voltage Driven Transparent Oxide Thin Film Transistors

Yang

Chien

Chang

et al. 2018

Physica Status Solidi (a)

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In this work, transparent ZnO thin‐film transistors (TFTs) are fabricated on ITO glass substrate with only solution processes. The active ZnO channels are deposited by spray pyrolysis. The gate dielectric is a spin‐coated high dielectric constant (k) titanium‐silicon oxide (TSO) layer, while the source/drain (S/D) electrodes are patterned by two‐step spray‐printing of silver nanowire (AgNWs)/poly(3,4‐ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) transparent conductive composite through a shadow mask. The composition and microstructural characteristics of the films, as well as their TFTs performance, are systematically studied as a function of the temperature. The introduction of TSO high k dielectric, with ultraviolet (UV)‐assisted post‐annealing, significantly improves the device performance and achieves a maximum electron mobility (µmax) value as high as 56.2 cm2 V−1 s−1 when measured with thermally‐evaporated Al top electrode. For fully solution‐processed transparent TFTs with low temperature fabricated AgNWs/PEDOT:PSS S/D electrodes, the µmax is calculated to be 9.1 cm2 V−1 s−1 operating at a relatively low voltage of <3 V. The TFTs also show hysteresis‐free electrical characteristics and optical transparency of ≈80% in the visible region of the optical spectrum.

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Gate Capacitance‐Dependent Field‐Effect Mobility in Solution‐Processed Oxide Semiconductor Thin‐Film Transistors

Cited by 88 publications

References 33 publications

Spray-combustion synthesis: Efficient solution route to high-performance oxide transistors

Spray-combustion synthesis: Efficient solution route to high-performance oxide transistors

Use of high-k encapsulation to improve mobility in trap-limited metal-oxide semiconductors

Fully Solution‐Processed Low‐Voltage Driven Transparent Oxide Thin Film Transistors

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