Oxygen '96

Early Stages of Oxygen Precipitation in Silicon

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ATOMIC COMPOSITION, STRUCTURE AND VIBRATIONAL EXCITATION OF SUBSTITUTIONAL CARBON-OXYGEN COMPLEXES IN SILICON

H. Yamada-Kaneta (a), Y. Shirakawa (a) and C. Kaneta (b)

(a) Process Development Div. Fujitsu Ltd., 1015 Kamikodanaka, Nakahara-ku, Kawasaki 211, JAPAN
(b) Electron Devices and Materials Laboratories, Fujitsu Laboratories Ltd., 10-1, Morinosato-wakamiya, Atsugi 243-01, JAPAN

The complexes of the substitutional carbon (C_s) and the interstitial oxygen (O_i) are the nuclei that promote the oxygen precipitation in silicon crystals. We investigated annealing behaviour of the intensities of the infrared absorption peaks A, B, B', C, C' and D of the C_s-O_i complexes observed at 1104, 1052, 1099, 1112, 1026 and 1108 cm^-1, respectively. In the early stage of the annealing, we found a quasi-thermal-equilibrium state in which the concentration of the (C_s)_m-(O_i)_n complexes (m, n : numbers of the carbon and oxygen atoms) are dominated by the mass-action law [(C_s)_m-(O_i)_n] = kappa(T) [C_s]^m[O_i]ⁿ. kappa(T) is an equilibrium reaction constant for the annealing temperature T. From the observed correlation between the peak intensities and the obtained formulas of the mass-action law (i.e. values of n), we found the following: The peaks A and D are due to the (C_s)₁-(O_i)₁ complex(es); the peaks B and B' are due to the (C_s)₁-(O_i)₂ complex; and the peaks C and C' are due to the (C_s)₁-(O_i)₃ complex.

For the peaks A, D, B and C, the measured temperature dependence of the intensity were somewhat weak, but similar to that of the 1136 cm^-1 peak of the isolated O_i. This indicates that the O_i in the complexes causing these peaks still has the 2-dimensional low-energy anharmonic excitation (2D LEAE) similar to that of isolated O_i. The weakened temperature dependence however suggests the weakened off-axis nature of the O_i causing these peaks. On the other hand, the intensities of the lower-energy peaks B' and C' hardly exhibited temperature dependence, implying that the O_i's causing these peaks no longer have the 2D LEAE and the off-centre nature. In other words, for the peak at the lower energy, the responsible O_i has the weaker off-axis nature. This tendency is explained by the expansion of the Si-Si distance of the Si-O-Si unit in the complex. From these arguments and the previous findings in the ab initio calculation, we speculate the possible atomic structures for the identified (C_s)₁-(O_i)_n complexes.

Last modified: Mon Feb 19 12:10:48 GMT 1996 JG