Investigation on electrical characteristics of TFTs fabricated with germanium films crystallized by atmospheric-pressure micro thermal plasma jet irradiation

Sato, Takuma; Hanafusa, Hiroaki; Higashi, Seiichiro

doi:10.35848/1347-4065/ac3d0b

Cited by 4 publications

(4 citation statements)

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“…An alternative approach involves crystallizing Ge films on SiO 2 substrates, employing solid phase crystallization 4) or energy beam-induced liquid phase crystallization. [5][6][7] However, these methods have resulted in forming only polycrystalline Ge films. We proposed the micro-chevron laser scanning (μCLS) method to form single crystal strips within silicon thin films on SiO 2 substrates.…”

Section: Introductionmentioning

confidence: 99%

“…In the case of Ge films, although single crystal growth was sustained for distances exceeding several tens of microns, 13) infinite crystal growth was not achieved through the μCLS method. Previous reports have indicated that the thickness of the capping film 5,23) on the Ge film and the nature of the interfacial layer 24,25) between the Ge film and the capping film significantly influences lateral crystal growth. We optimized the materials and thicknesses of the interface layer and cap layer for the 60 nm Ge film to achieve continuous lateral growth using μCLS.…”

Section: Introductionmentioning

confidence: 99%

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Infinite lateral growth of (001) single crystal strip in Ge film on SiO₂ by micro-chevron laser scanning method

Yeh,

Osato

2024

Jpn. J. Appl. Phys.

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Ge single crystal strip having a dominant crystal orientation of (001)<100> was grown in 60nm-thick sputter Ge film by micro-chevron laser scanning (µCLS) method, without grain boundary (>1o) crossing the strip. The key of continuous lateral growth is thick cap layer and SiO2 interlayer between Ge layer and cap layer. Thick cap layer work as heat sink and increased melt duration of Ge film to prevent nu-cleation. Yaw rotation of (001) crystal that pull the trigger of grain boundary in Si is negligible in Ge. This provides evidence for infinite lateral growth of (001) Ge strip. Raman shifts of the single crystal strip was 297.4 cm-1, indicating that the film was with tensile stress.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Infinite lateral growth of (001) single crystal strip in Ge film on SiO₂ by micro-chevron laser scanning method

Yeh,

Osato

2024

Jpn. J. Appl. Phys.

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“…To integrate Ge-CMOS into electronic devices, including three-dimensional large-scale integrated circuits or flat panel displays, it is necessary to form a high-quality Ge layer at low temperatures that does not damage the substrate or surrounding devices. Fortunately, the crystallization temperature of Ge is lower than that of Si, and many low-temperature synthesis methods have been proposed, including solid-phase crystallization (SPC), − laser annealing, − chemical vapor deposition, , lamp annealing, , plasma irradiation, seed layer technique, and metal-induced crystallization. − Although these methods produce polycrystalline Ge layers containing grain boundaries, large grain size and grain boundary control enable quasi-single-crystal channels in transistors. ,,, Most of these polycrystalline Ge films are p-type, whereas reports on n-type Ge have been limited. This is because Ge tends to be p-type owing to the high density (10 17 –10 18 cm –3 ) of acceptor defects , and low n-type dopant activation rates. , Therefore, the synthesis of high-quality polycrystalline Ge layers is essential for obtaining n-type Ge layers in low-temperature processes.…”

Section: Introductionmentioning

confidence: 99%

n-Type Polycrystalline Germanium Layers Formed by Impurity-Doped Solid-Phase Growth

Nozawa

Nishida

Ishiyama

et al. 2023

ACS Appl. Electron. Mater.

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The carrier mobility of polycrystalline Ge thin-film transistors has significantly improved in recent years, raising hopes for the realization of next-generation electronic devices. Here, we adapted advanced solid-phase crystallization, which achieved the highest hole mobility of the polycrystalline semiconductor layer, to Ge layers doped with n-type impurities (P, As, and Sb). The type and amount of dopants had marked effects on the growth morphology and electrical properties of the Ge layers because they altered the activation energies in crystal growth, dopant activation rates, and grain boundary properties. In particular, P doping was effective in increasing the grain size (25 μm) and lowering the grain boundary barrier height (20 meV), which improved the electron concentration (8.0 × 1018 cm–3) and electron mobility (380 cm2 V–1 s–1) in n-type polycrystalline Ge layers. The electron mobility is greater than that of most semiconductor layers synthesized at low temperatures (≤500 °C) on insulators, and this will pave the way for advanced electronic devices, such as multifunctional displays and three-dimensional large-scale integrated circuits.

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“…Techniques for synthesizing thin films of high-mobility materials on insulating substrates have been extensively studied. Ge has been a preferred TFT channel material owing to its high carrier mobility and relatively low crystallization temperature. , The performance of metal-oxide semiconductor field-effect transistors (MOSFETs) based on single-crystal Ge (sc-Ge) has surpassed that of Si MOSFETs because of the gate stack technologies − and thin-film structure. − To date, polycrystalline Ge (poly-Ge) thin films have been synthesized at low temperatures using various techniques, such as solid-phase crystallization (SPC), − laser annealing, − chemical vapor deposition, − lamp annealing, − plasma irradiation, seed layer technique, and metal-induced crystallization. − However, owing to the poor quality of poly-Ge, particularly in thin films (<100 nm), which are required for reducing the off-current of TFTs, the practical use of poly-Ge-based TFTs on glass has yet to be achieved.…”

Section: Introductionmentioning

confidence: 99%

Interfacial Nucleation Control in Amorphous GeSn Thin Films Using Bilayer Structure

Maeda

Ishiyama

Saitoh³

et al. 2023

Crystal Growth & Design

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Remarkable progress has been made in germanium-based thin-film transistors in recent years. However, achieving both high field-effect mobility and a high on–off ratio is difficult because the crystallinity of polycrystalline Ge degrades as it becomes thinner. In this study, we investigated the interfacial nucleation control and grain size enlargement in the solid-phase crystallization of amorphous Ge thin films (≤50 nm). A bilayer structure consisting of top nucleation and bottom nucleation suppression layers promoted nucleation at the surface rather than at the substrate interface, resulting in a significant enlargement of the grain size. In addition, Sn doping in Ge increased the grain size to 12 μm, which was larger than that of most polycrystalline Ge thin films and contributed to the reduction in acceptor defects and improvement in hole mobility. The resulting hole mobility (260 cm2 V–1 s–1) and hole concentration (3 × 1017 cm–3) in the GeSn layer were among the highest for polycrystalline Ge-based thin films. These results will contribute to the realization of low-temperature Ge-based thin-film transistors that could be superior to single-crystal Si transistors, leading to innovations in display devices.

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Investigation on electrical characteristics of TFTs fabricated with germanium films crystallized by atmospheric-pressure micro thermal plasma jet irradiation

Cited by 4 publications

References 44 publications

Infinite lateral growth of (001) single crystal strip in Ge film on SiO₂ by micro-chevron laser scanning method

Infinite lateral growth of (001) single crystal strip in Ge film on SiO₂ by micro-chevron laser scanning method

n-Type Polycrystalline Germanium Layers Formed by Impurity-Doped Solid-Phase Growth

Interfacial Nucleation Control in Amorphous GeSn Thin Films Using Bilayer Structure

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Investigation on electrical characteristics of TFTs fabricated with germanium films crystallized by atmospheric-pressure micro thermal plasma jet irradiation

Cited by 4 publications

References 44 publications

Infinite lateral growth of (001) single crystal strip in Ge film on SiO2 by micro-chevron laser scanning method

Infinite lateral growth of (001) single crystal strip in Ge film on SiO2 by micro-chevron laser scanning method

n-Type Polycrystalline Germanium Layers Formed by Impurity-Doped Solid-Phase Growth

Interfacial Nucleation Control in Amorphous GeSn Thin Films Using Bilayer Structure

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Infinite lateral growth of (001) single crystal strip in Ge film on SiO₂ by micro-chevron laser scanning method

Infinite lateral growth of (001) single crystal strip in Ge film on SiO₂ by micro-chevron laser scanning method