The two dimensional (2D) diffusion of self-interstitials (I) in crystalline Si, both at room temperature and at 800 °C, has been studied by quantitative SCM measurements. The 2D I emission from a I source laterally confined down to sub-micron dimensions, obtained by low-energy implantation through a patterned oxide mask, has been observed. At room temperature, / diffusion was monitored by measuring the electrical deactivation of B corresponding to the diffusing interstitial tail and it was demonstrated that this deactivation is due to compensating levels introduced by defects in the Si bandgap. At 800 °C I diffusion was monitored by measuring the transient enhanced diffusion of B spikes due to interstitial supersaturation produced during the annealing. In both cases, a dependence of the I depth-penetration on the original source size has been shown for mesoscopic window openings (from 0. 5 to 3 μm)
Two dimensional interstitial diffusion in mesoscopic structures
DE SALVADOR, DAVIDE;NAPOLITANI, ENRICO;
2004
Abstract
The two dimensional (2D) diffusion of self-interstitials (I) in crystalline Si, both at room temperature and at 800 °C, has been studied by quantitative SCM measurements. The 2D I emission from a I source laterally confined down to sub-micron dimensions, obtained by low-energy implantation through a patterned oxide mask, has been observed. At room temperature, / diffusion was monitored by measuring the electrical deactivation of B corresponding to the diffusing interstitial tail and it was demonstrated that this deactivation is due to compensating levels introduced by defects in the Si bandgap. At 800 °C I diffusion was monitored by measuring the transient enhanced diffusion of B spikes due to interstitial supersaturation produced during the annealing. In both cases, a dependence of the I depth-penetration on the original source size has been shown for mesoscopic window openings (from 0. 5 to 3 μm)Pubblicazioni consigliate
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