150mm Silicon Carbide Selective Embedded Epitaxial Growth Technology by CVD

Hara, Kimiko; Fujibayashi, Hiroaki; Takeuchi, Yuuichi; Omae, Shoichiro

doi:10.4028/www.scientific.net/msf.897.43

Cited by 7 publications

(5 citation statements)

References 7 publications

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“…However, to fill a trench deeper than 5 μm which takes a long growth duration, merely reviewing R G-TB is thought to be inadequate, since the epilayer on mesa grown at R G-MT >0 perhaps closes the trench during the long growth duration. To make an overall evaluation of all aspects, a growth ratio factor of filling process is formulated, which is defined as η Fill =R G-TB /(R G-MT +R G-TB ) [9]. Figure 1(c) shows a growth ratio factor map attained on 5-μm trenches.…”

Section: Resultsmentioning

confidence: 99%

CVD Filling of Narrow Deep 4H-SiC Trenches in a Quasi-Selective Epitaxial Growth Mode

Kosugi

Kojima

et al. 2018

MSF

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By mapping the source and HCl flow rates dependent growth rates, the evolving trend of a quasi-selective epitaxial growth (quasi-SEG) that growing very thin epilayer on mesa top and ensuring an extremely low risk of voids defect generation was firstly figured out on a 5-μm 4H-SiC trench. Then, basing on the acquired knowledge, a 25-μm 4H-SiC trench with an aspect ratio up to ~10 was completely filled in the quasi-SEG mode.

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Section: Resultsmentioning

confidence: 99%

CVD Filling of Narrow Deep 4H-SiC Trenches in a Quasi-Selective Epitaxial Growth Mode

Kosugi

Kojima

et al. 2018

MSF

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“…After correction: , where 46-keV 11 B, 59-keV 14 N, 114 keV 27 Al, and 131-keV 31 P ions were implanted at a dose of 1.3 × 10 13 cm −2 . Maximum channeled range (R max ) is defined as the depth where concentration decreases to 10% of its channeled peak concentration.…”

Section: Before Correctionmentioning

confidence: 99%

“…6. (Color online) Secondary-ion mass spectrometry measured depth profiles of channeled-ion implantations into 4H-SiC (0001) at a velocity of 9 × 10 7 cm −2 , where 46-keV 11 B, 59-keV 14 N, 114-keV 27 Al, and 131-keV Before correction:…”

Section: Before Correctionmentioning

confidence: 99%

“…Although a trench-etching-and-sidewall-implant method has been used to fabricate 1.35-kV SiC SJ Schottky diodes, 7,8) an increase in BV (i.e., trench depth > 6 μm) is limited by the difficulty in the sidewall implant with an incident angle more than 70°. 7,8) Large BV can be attained using a trench-filling epitaxial growth method; [9][10][11][12][13][14][15] however, complete filling of SiC around the trench edge has yet to be attained. 16) In contrast, a multiepitaxial growth method (ME), in which epitaxial growth and ion implantation are repeated alternately until a certain driftlayer thickness is achieved, has been successfully employed; namely, 1.54-kV SJ p-n diodes 17) and 0.82-kV SJ V-groove trench MOSFETs 18) fabricated using 9 MeV Al-ion implantation, as well as 1.17-kV SJ V-groove trench MOSFETs 19) and 1.2 kV-class SJ trench MOSFETs 20) fabricated using sub-MeV Al-ion implantation.…”

Section: Before Correctionmentioning

confidence: 99%

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Selection of ion species suited for channeled implantation to be used in multi-epitaxial growth for SiC superjunction devices

Mochizuki

Kosugi

Yonezawa

et al. 2019

Jpn. J. Appl. Phys.

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Recently, we found a mistake in the depth profile of channeled-ion implantation into 4H-SiC (0001), where 114-keV 27 Al ions were implanted at a dose of 1.3 × 10 13 cm −2 . However, the discussion of the manuscript is unchanged. We would like to apologize for any inconvenience.The sentence and figures related to the depth profile of channeled-ion implantation into 4H-SiC ( 0001), where 114-keV 27 Al ions were implanted at a dose of 1.3 × 10 13 cm −2 , written on page 050905-3 should be corrected as shown below: line 14-16: Before correction: "As shown in Fig. 6, R max is 0.29 μm for N, 0.32 μm for B, 0.67 μm for P, and 1.06 μm for Al".After correction: "As shown in Fig. 6, R max is 0.29 μm for N, 0.32 μm for B, 0.67 μm for P, and 0.99 μm for Al". 31 P ions were implanted at a dose of 1.3 × 10 13 cm −2 . Maximum channeled range (R max ) is defined as the depth where concentration decreases to 10% of its channeled peak concentration. 21)

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“…Recently, epitaxial growth technology towards selective growth of 4H-SiC epitaxial film to realize high performance power devices with trench structure has been investigated. It has been reported that the 4H-SiC epitaxial film is satisfactorily filled in the trench by adding HCl gas with a high Cl/Si ratio of about 30 in CVD process [1,2]. However, most of previous reports have been focused on filling characteristics of the SiC in the trench, and defect formation on the planar substrate grown at the same condition has not been investigated.…”

Section: Introductionmentioning

confidence: 99%

Origin of Large Bumps Abnormally Grown on 4H-SiC Epitaxial Film by Adding HCl Gas with High Cl/Si Ratio in CVD Process

Daigo¹,

Ishiguro²

2020

MSF

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4H-SiC homo-epitaxial film was grown by adding HCl gas with a high Cl/Si ratio in CVD process, and defect formation and origin of the defect were investigated by confocal differential interference contrast (CDIC) microscope, PL imaging and normal differential interference contrast (DIC) microscope. It was found that a large number of large bumps are formed on the film grown at a high Cl/Si ratio of 30, and a large number of PL defects on bare substrate before the film growth are also observed. Coordinates where the bumps on the film are observed were good agreement with those where the PL defects on the bare substrate are observed. An etch pit sample on reproduced substrate from which epitaxial film was removed was fabricated by etching process using molten KOH+Na2O2, and some types of etch pits which might be originated from threading edge dislocations (TEDs), threading screw dislocations (TSDs) and basal plane dislocations (BPDs) in the substrate were observed. The coordinates where the etch pits on the reproduced substrate are observed were also good agreement with those where the bumps on the epitaxial film are observed. Therefore, it was clarified that a large number of the bumps abnormally grown on the epitaxial film are originated from the dislocations in the substrate.

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150mm Silicon Carbide Selective Embedded Epitaxial Growth Technology by CVD

Cited by 7 publications

References 7 publications

CVD Filling of Narrow Deep 4H-SiC Trenches in a Quasi-Selective Epitaxial Growth Mode

CVD Filling of Narrow Deep 4H-SiC Trenches in a Quasi-Selective Epitaxial Growth Mode

Selection of ion species suited for channeled implantation to be used in multi-epitaxial growth for SiC superjunction devices

Origin of Large Bumps Abnormally Grown on 4H-SiC Epitaxial Film by Adding HCl Gas with High Cl/Si Ratio in CVD Process

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