First-Principles Study of P-Doped 6H-SiC

Abstract

Abstract: The electronic structure and optical properties of intrinsic 6H-SiC, P substituted for Si, C doped and P interstitial doped 6H-SiC were calculated by the first-principles pseudopotential plane wave method based on density functional theory. The results indicate that intrinsic 6H-SiC is an indirect band gap semiconductor with a band gap of 2.052 eV. The band gaps of the P substituted for Si, C doped and P interstitial doped 6H-SiC decrease to 1.787 eV, 1.446 eV and 0.075 eV, respectively. The interstitial doping band gap decreases the most. P substitutional doped 6H-SiC causes the Fermi level guide band to move and insert into the conduction band, and the 6H-SiC becomes an n-type semiconductor. One level of P interstitial doping valence band crosses into Fermi level, so a P 3p impurity level appears in the gap band, and 6H-SiC turns into p-type semiconductor. Substitutional and interstitial doping increase the real part of dielectric function of 6H-SiC, while the imaginary part of dielectric function, absorption spectrum, reflection spectrum and photoconductivity redshift. Among them, P interstitial doped 6H-SiC has the best effect. The conductivity of the material is enhanced and the utilization rate of the material in the infrared band is obviously improved by P doping. The results provide effective theoretical basis for the application of 6H-SiC in infrared photoelectric performance.

Key words: gap doping, 6H-SiC, band gap, dielectric function, first-principle, electronic structure, optical property

CLC Number:

O469

HUANG Sili, XIE Quan, ZHANG Qin. First-Principles Study of P-Doped 6H-SiC[J]. JOURNAL OF SYNTHETIC CRYSTALS, 2022, 51(1): 49-55.

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