Relation between electrical activation and the B-induced strain in Si determined by reciprocal lattice mapping

Boron-induced strain in Si epilayers was characterized by using high-resolution x-ray reciprocal lattice mapping. Samples grown by molecular beam epitaxy with high crystalline quality and full electrical activation of dopants with concentrations from 2x10 super(19) cm super(-3) up to ) 1x10 super(21...

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Bibliographic Details
Published in:Semiconductor science and technology 1994-06, Vol.9 (6), p.1272-1275
Main Authors: Jr, M R Sardela, Radamson, H H, Ekberg, J O, Sundgren, J -E, Hansson, G V
Format: Article
Language:English
Subjects:
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Conductivity phenomena in semiconductors and insulators
Electronic transport in condensed matter
Exact sciences and technology
Low-field transport and mobility
piezoresistance
Physics
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Summary:Boron-induced strain in Si epilayers was characterized by using high-resolution x-ray reciprocal lattice mapping. Samples grown by molecular beam epitaxy with high crystalline quality and full electrical activation of dopants with concentrations from 2x10 super(19) cm super(-3) up to ) 1x10 super(21) cm super(-3) were employed, with measured lattice mismatches up to ) 0.5% (tetragonal strain ) 1%). The measured lattice contraction coefficient, beta , was (5.6 plus or minus 0.1)x10 super(-24) cm super(3)/atom, by considering the ratio of the lattice mismatch to the total dopant concentration. However, by considering only the effectively incorporated and activated dopant concentration, given by the measured carrier concentration, beta was found to be (6.3 plus or minus 0.1)x10 super(-24) cm super(3)/atom. Further measurements on B-doped structures grown at high temperatures ( greater than or equal to 600 degree C), which had only partial electrical activation ( < 20%), confirmed that the B-induced lattice contraction in Si is related not to the total dopant concentration, but rather to the carrier concentration, which in principle corresponds to the active and substitutionally incorporated dopants. The high accuracy of our strain measurements was facilitated by the reciprocal lattice mapping method. In-plane and normal components (relative to the sample surface) of the lattice parameter of the epilayers were measured independently, and minute variations in the strain/relaxation status of the structures were accounted for.
ISSN:0268-1242
1361-6641
DOI:10.1088/0268-1242/9/6/020