E. Wendler et al., ANNEALING STUDIES OF B-SIC BY RBS AND OPTICAL SUBGAP SPECTROSCOPY( IMPLANTED 6H), Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms, 127, 1997, pp. 341-346
B+ ions were implanted into 6H-SiC at room temperature and annealing w
as performed in nitrogen ambient at temperatures up to 450 degrees C o
r 1000 degrees C. The layers were analyzed by Rutherford backscatterin
g-channeling spectrometry and sup-gap optical spectroscopy yielding th
e depth and the spectral dependence of the absorption coefficient and
the refractive index, In the case of a very low defect concentration o
btained by implantation of 7 x 10(13) B(+)cm(-2) a temperature of 1000
degrees C is necessary to remove the absorbing point defects and poin
t defect complexes. The annealing of an amorphous SIC layer (ion dose
1 x 10(16) B(+)cm(-2)) at temperatures between 300 degrees C and 450 d
egrees C is connected with an increase of the optical gap energy (i.e.
with a decrease of the absorption coefficient), and with a decrease o
f the refractive index and of the swelling of the layer, These effects
seem to be connected with the relaxation of the amorphous network. A
SiC layer of an intermediate defect state was obtained after implantat
ion of 2 x 10(15) B(+)cm(-2). The results indicate that this layer con
tains amorphized SiC regions surrounded by weakly damaged crystalline
SiC, From the analysis of the optical spectra it can be concluded that
already after annealing at temperatures up to 400 degrees C the amoun
t of amorphous SIC decreases remarkably.