Extended Abstracts of the 2017 International Conference on Solid State Devices and Materials 2017
DOI: 10.7567/ssdm.2017.k-4-04
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Hot-C<sup>+</sup>-Ion Implantation Optimization for Forming Nano-SiC Region at Surface (100)SOI Substrate

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“…In addition, we studied nano-SiC material structures in the C atom segregation layer, by atom probe tomography (ATP) for the 3D distribution of C atoms, 22) corrector-spherical aberration transmission electron microscopy (CSTEM), and PL properties excited by a 3.8 eV laser at room temperature. 23) We successfully observed 3C-SiC and 4H-SiC nanoareas in the C segregation layer. We demonstrated that the PL intensity, which is emitted from the surface C segregation layer, strongly depends on hot-C-ion implantation temperature and C ion dose, but the PL peak photon energy E PH shows a weak dependence on hot-C-ion implantation temperature and C ion dose.…”
Section: Introductionmentioning
confidence: 77%
“…In addition, we studied nano-SiC material structures in the C atom segregation layer, by atom probe tomography (ATP) for the 3D distribution of C atoms, 22) corrector-spherical aberration transmission electron microscopy (CSTEM), and PL properties excited by a 3.8 eV laser at room temperature. 23) We successfully observed 3C-SiC and 4H-SiC nanoareas in the C segregation layer. We demonstrated that the PL intensity, which is emitted from the surface C segregation layer, strongly depends on hot-C-ion implantation temperature and C ion dose, but the PL peak photon energy E PH shows a weak dependence on hot-C-ion implantation temperature and C ion dose.…”
Section: Introductionmentioning
confidence: 77%
“…19,28) Recently, we have experimentally studied a Si 1-Y C Y layer fabricated by hot-12 C + -ion implantation into a (100) SOI with an approximately 100 nm thick surface oxide (SOX) at a high substrate temperature T and heavy C + ion dose D C in the wide range of 500 °C ⩽ T ⩽ 1000 °C, 5 × 10 12 ⩽ D C ⩽ 7 × 10 16 cm −2 (0.01 < Y ⩽ 0.3), and 0.5 ⩽ d S ⩽ 20 nm. [30][31][32][33] According to the self-cluster effects of ion implanted C atoms with the C cluster size of several nm in a crystal-Si (c-Si) layer [33][34][35] analyzed by atom probe tomography (ATP), C content in the c-Si locally condenses both at the SOX/Si and buried-oxide (BOX)/Si interfaces in c-Si layer, which leads to the local formation of SiC dots in c-Si. [30][31][32][33] The hot-C + -ion implantation process can reduce the ion implantation induced damage of the Si layer.…”
Section: Introductionmentioning
confidence: 99%
“…[30][31][32][33] According to the self-cluster effects of ion implanted C atoms with the C cluster size of several nm in a crystal-Si (c-Si) layer [33][34][35] analyzed by atom probe tomography (ATP), C content in the c-Si locally condenses both at the SOX/Si and buried-oxide (BOX)/Si interfaces in c-Si layer, which leads to the local formation of SiC dots in c-Si. [30][31][32][33] The hot-C + -ion implantation process can reduce the ion implantation induced damage of the Si layer. 31) Under a heavy C dope condition of higher than 2 × 10 16 cm −2 , X-ray photoelectron spectroscopy (XPS) and ATP showed that C atoms segregate with an approximately 2 nm thickness at both the SOX/Si and BOX/Si interfaces.…”
Section: Introductionmentioning
confidence: 99%
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