We present a study for large defects called protrusions that form during the hetero-epitaxy of SiC on Si. We focus first on surface morphology, size, three-dimensional shape and internal structure, and second on photoluminescence and Raman features. These defects have a peculiar 3D structure similar to inverted square pyramids with a vertex close to the SiC/Si interface. The size of the square and the height of the pyramid are both related to the thickness of the epi-layer and are spatially limited by the stacking faults in the {111} planes. The inner core of the defect consists of nano crystals twinned with respect to the substrate orientation. The defects demonstrate broad peculiar emission band at about 750 nm, while the usual photoluminescence signal from band recombination is at 520 nm. The SiC/Si interface is studied in order to investigate the seed of protrusion defect formation. We found that seeds responsible for the formation of protrusions lie 10 nm above the SiC/Si interface. This indicates that protrusion forms after the carbonization process, in particular in the temperature ramp up after carbonization. Modifying the Si/C ratio and some other growth parameters in the post-carbonization process we succeed in reducing the density of protrusion to less than 10 cm(-)(2).

Protrusions reduction in 3C-SiC thin film on Si

Zimbone Massimo;Bongiorno Corrado;La Via Francesco
2018

Abstract

We present a study for large defects called protrusions that form during the hetero-epitaxy of SiC on Si. We focus first on surface morphology, size, three-dimensional shape and internal structure, and second on photoluminescence and Raman features. These defects have a peculiar 3D structure similar to inverted square pyramids with a vertex close to the SiC/Si interface. The size of the square and the height of the pyramid are both related to the thickness of the epi-layer and are spatially limited by the stacking faults in the {111} planes. The inner core of the defect consists of nano crystals twinned with respect to the substrate orientation. The defects demonstrate broad peculiar emission band at about 750 nm, while the usual photoluminescence signal from band recombination is at 520 nm. The SiC/Si interface is studied in order to investigate the seed of protrusion defect formation. We found that seeds responsible for the formation of protrusions lie 10 nm above the SiC/Si interface. This indicates that protrusion forms after the carbonization process, in particular in the temperature ramp up after carbonization. Modifying the Si/C ratio and some other growth parameters in the post-carbonization process we succeed in reducing the density of protrusion to less than 10 cm(-)(2).
2018
3C-SiC
Protrusions
C/Si ratio
Post-carbonization process
File in questo prodotto:
Non ci sono file associati a questo prodotto.

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/400410
Citazioni
  • ???jsp.display-item.citation.pmc??? ND
  • Scopus ND
  • ???jsp.display-item.citation.isi??? 15
social impact