The authors previously reported an unusual phenomenon of strain relaxation accompanied by a reduction in threading dislocation density (TDD) on a Si0.77Ge0.23 layer grown on top of alternating layers of Si0.77Ge0.23Si0.76Ge0.23C0.01 [Appl. Phys. Lett.88, 041915 (2006)]. In this letter, the mechanism by which SiGeC domains, formed during annealing at 1000°C, assist in TDD annihilation process is further investigated. A gb analysis of transmission electron microscope images showed the formation of pure edge dislocations from the reaction of two 60° misfit dislocations, which glide and/or slip with the assistance of the localized interfacial strain of the SiGeC domains. TDD reduction in this structure is thus due to the annihilation of threading dislocation arms during misfit dislocation combination.

Topics
Microelectronic devices, Electrical properties and parameters, Heterostructures, Crystallographic defects, Crystal lattices, Epitaxy, Annealing, Mechanical stress, Transmission electron microscopy, Surface and interface chemistry
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© 2006 American Institute of Physics.
2006
American Institute of Physics
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