Al and B ion-implantations in 6H- and 3C-SiC

Rao, Mulpuri V.; Griffiths, Peter R.; Holland, O. W.; Kelner, G.; Freitas, J. A.; Simons, David S.; H., P.; Ghezzo, M.

doi:10.1063/1.358776

Cited by 111 publications

(36 citation statements)

References 27 publications

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“…[2][3][4] Ion implantation at elevated temperatures ͑hot implantation͒ is known to reduce damage and enhance the activation of impurities, but it also introduces extended defects such as dislocation loops, which degrade the electrical properties. 3,5,6 For compound semiconductors, ion beam induced epitaxial crystallization ͑IBIC͒ often produces better crystal quality than thermal annealing, but for SiC, the mechanism of IBIC is complex and still under investigation. 7 Therefore, the study of the annealing behavior of defects in ion-implanted SiC is important for fabricating SiC devices.…”

Section: Introductionmentioning

confidence: 99%

Crystallization of an amorphous layer in P+-implanted 6H-SiC studied by monoenergetic positron beams

Uedono

Tanigawa

Ohshima³

et al. 2000

Journal of Applied Physics

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Depth distributions and species of defects were determined from measurements of Doppler broadening spectra of annihilation radiation and lifetime spectra of positrons for 6H-SiC implanted with 200 keV P+ at a dose of 1×1015 cm−2. The annealing behavior of an amorphous layer was divided into four stages. Stages I (100–500 °C) and II (500–1100 °C) were identified as the relaxation of amorphous networks and the agglomeration of open spaces owing to rearrangements of atoms, respectively. In states III (1100–1500 °C) and IV (1500–1700 °C), corresponding to the recrystallization of the amorphous layer, the mean size of the open volume of defects decreased with increasing annealing temperature; these defects were identified as open spaces adjacent to extended defects. Vacancy-type defects were found in the subsurface region (<100 nm) at high concentration even subsequent to an annealing at 1700 °C. The annealing behavior of defects in the specimens irradiated at elevated temperatures is also discussed.

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Section: Introductionmentioning

confidence: 99%

Crystallization of an amorphous layer in P+-implanted 6H-SiC studied by monoenergetic positron beams

Uedono

Tanigawa

Ohshima³

et al. 2000

Journal of Applied Physics

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“…The only difference observed between the two spectra are the weak sharp lines at 2.623 eV, 2.588 eV, and 2.586 eV in the implanted sample. These lines are associated with defects induced by the ion implantation [9]. The relatively small intensity of these lines and the similarity between both spectra, suggested that the annealing treatment has recovered the crystalline quality of the substrate.…”

Section: Resultsmentioning

confidence: 87%

Microwave Annealing of Ion Implanted 6H-SiC

et al. 1996

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Microwave rapid thermal annealing has been utilized to remove the lattice damage caused by nitrogen (N) ion-implantation as well as to activate the dopant in 6H-SiC. Samples were annealed at temperatures as high as 1400 °C, for 10 min. Van der Pauw Hall measurements indicate an implant activation of 36%, which is similar to the value obtained for the conventional furnace annealing at 1600 °C. Good lattice quality restoration was observed in the Rutherford backscattering and photoluminescence spectra.

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“…Lattice damage that occurs in SiC during implantation can be minimized by performing ion implantation at a high temperature, around 800°C. [15][16][17] While aluminum implants in SiC have been found to be stable during annealing, [18][19][20] substantial dopant re-distribution of boron 10 and gallium 21 has been observed during annealing leading to dopant loss or gettering at the SiC surface as a result of Si evaporation from the lattice. Additionally, degradation of the surface leads to an increase in the number of surface traps and an unwanted decrease in carrier mobility in surface channel regions.…”

Section: Introductionmentioning

confidence: 97%