SiC Migration Enhanced Embedded Epitaxial (ME&lt;sup&gt;3&lt;/sup&gt;) Growth Technology

Takeuchi, Yuuichi; Kataoka, Mitsuhiro; Kimoto, Tsunenobu; Matsunami, Hiroyuki; Malhan, Rajesh Kumar

doi:10.4028/www.scientific.net/msf.527-529.251

Cited by 20 publications

(27 citation statements)

References 5 publications

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“…The parameter a is almost constant in the temperature range of 1450 °C to 1650 °C. From a fitted linear line in Arrhenius plot configuration, the extracted surface migration activation energy is about 65 kcal/mol, which is higher compared with standard growth conditions [34,35].…”

Section: Innovative Device Process Technologiesmentioning

confidence: 99%

Design, process, and performance of all‐epitaxial normally‐off SiC JFETs

Malhan

Bakowski

Takeuchi

et al. 2009

Physica Status Solidi (a)

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This paper reviews the normally‐off (N‐ off) and normally‐on (N‐ on) SiC junction field effect transistor (JFET) concepts and presents an innovative all‐epitaxial double‐gate trench JFET (DGTJFET) structure. The DGTJFET design combines the advantages of lateral and buried gate JFET concepts. The lateral JFET advantage is the epitaxial definition of the channel width and the buried gate JFET advantage is the small cell size. In the DGTJFET process the epitaxial embedded growth in trenches facilitates the small cell pitch and the vertical direction of the channel. A detailed numerical simulation analysis compares the potential of the DGTJFET design with reported lateral channel and buried gate JFET structures. Migration enhanced embedded epitaxy (ME3) and planarization processes were developed to realize narrow cell pitch DGTJFETs for high‐density power integration. The highly doped vertical channel of the DGTJFET defined by the ME3 growth process makes it possible to accurately control the sub‐micron channel dimensions in order to realize a low specific on‐state resistance (RON) and a high saturation current capability. The anisotropic nature of SiC is taken into account for the channel design considerations. The successful application of the new process technologies for the development of the all‐epitaxial DGTJFETs is discussed. Fabricated 5.5 μm cell pitch 4H‐SiC DGTJFETs demonstrate the saturation current density capability of more than 1000 A/cm2. N‐ off and N‐ on DGTJFETs with 2.25 mm squared chip size and 9.5 μm cell pitch output 15 A and 20 A at gate voltage of 2.5 V and drain voltage of 5.0 V. The specific RON of the N‐ off and N‐ on DGTJFETs is at room temperature 8.1 m Ω cm2 and 6.3 mΩ cm2, respectively, indicating that N‐ off devices can be realized at the expense of a slight increase in specific RON of approximately 25%. DGTJFETs with a 13 μm drift layer doped to 5.0 × 1015 cm–3 are demonstrated with a breakdown voltage in the range of 1200 V to 1550 V at the wafer level with a leakage current below 10 μA. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Section: Innovative Device Process Technologiesmentioning

confidence: 99%

Design, process, and performance of all‐epitaxial normally‐off SiC JFETs

Malhan

Bakowski

Takeuchi

et al. 2009

Physica Status Solidi (a)

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“…9,10) The line (L) and space (S) dimensions of the line pattern on the mask used for trench lithography were 1 and 1.5 µm, respectively, and the trench depths (D) were about 4.7 and 5 µm, respectively. The HWCVD system with a rotary substrate was utilized.…”

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“…7) Therefore, trench filling by epitaxially filling doped SiC into trenches of the opposite conductivity type is considered the preferable method for constructing SiC-SJ structures. [8][9][10][11][12][13][14] In previous literature, 4H-SiC trenches with depths of up to 7 µm and aspect ratios of about 2-4 have been completely or half-filled by using hot-wall chemical vapor deposition (HWCVD) with a conventional gas system, SiH 4 : C 3 H 8 : H 2 . [8][9][10][11][12][13] However, Schöner et al mentioned the necessity of maintaining a slow growth rate and long duration of trench filling to minimize excessive growth outside of the trenches.…”

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confidence: 99%

“…[8][9][10][11][12][13][14] In previous literature, 4H-SiC trenches with depths of up to 7 µm and aspect ratios of about 2-4 have been completely or half-filled by using hot-wall chemical vapor deposition (HWCVD) with a conventional gas system, SiH 4 : C 3 H 8 : H 2 . [8][9][10][11][12][13] However, Schöner et al mentioned the necessity of maintaining a slow growth rate and long duration of trench filling to minimize excessive growth outside of the trenches. 13) Though few details have been released, it is conjectured that the motivation for minimizing the growth outside of the trenches was to avoid the potential risk of void formation (fast closing around the trench's top corner) during long-duration growth.…”

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“…Apparently, overgrowth on the mesa requires the additional process of device planarization (polishing) after the growth, and therefore, it degrades productivity. [8][9][10][11] In the CVD filling of a Si trench, to minimize the excessive growth on the mesa top and trench top corner, Yamauchi et al reported a nonmasked method of filling Si trenches by flowing HCl and SiH 2 Cl 2 together. HCl was added to prevent growth around the trench tops, which was predicted based on the fact that the reaction of Cl-Si is faster than that of Si-Si.…”

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Filling 4H-SiC trench towards selective epitaxial growth by adding HCl to CVD process

Kojima

Kosugi

et al. 2015

Appl. Phys. Express

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In this study, 4H-SiC stripe-shaped trenches preformed on an n + substrate were filled by adding HCl to the chemical vapor deposition process at relatively high pressures. HCl was found capable of counterbalancing the deposition on the mesa top by strong etching, and it thus enabled quasiselective epitaxial growth across the whole extents of the trenches, where the epilayer preferentially grows from the trench bottom. Using the established technique, the 1-µm-wide 4H-SiC trenches, with an aspect ratio of 5, which is the highest aspect ratio to date, were completely filled at a growth rate above 0.5 µm/h and acquired a flat end surface.

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Epitaxial Growth of Silicon Carbide

Kimoto¹,

Cooper

2014

Fundamentals of Silicon Carbide Technology

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SiC Migration Enhanced Embedded Epitaxial (ME<sup>3</sup>) Growth Technology

Cited by 20 publications

References 5 publications

Design, process, and performance of all‐epitaxial normally‐off SiC JFETs

Design, process, and performance of all‐epitaxial normally‐off SiC JFETs

Filling 4H-SiC trench towards selective epitaxial growth by adding HCl to CVD process

Epitaxial Growth of Silicon Carbide

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