Threading dislocation reduction in (0001) GaN thin films using SiNx interlayers

Abstract The ability of in situ SiN x interlayers to lower the density of threading dislocations (TDs) has been studied for the growth of c -plane (0 0 0 1) GaN epilayers on sapphire by organometallic vapour-phase epitaxy (OMVPE). The TD density in the films may be reduced by up to a factor of 50 to 9×10 7  cm −2 and depends on the SiN x coverage and the conditions of the overgrowth. The TD reduction method relies on the formation of facetted islands on the SiN x -treated GaN surface and the formation of dislocation half-loops between bent-over TDs during the lateral overgrowth. Dislocations that are not annihilated at the interfacial region during the interlayer overgrowth may bend over at the islands’ inclined side facets and annihilate at their coalescence boundaries. Thus, the TD density was reduced at the expense of greater film thickness by increasing the SiN x coverage and delaying intentionally the coalescence of the GaN islands.

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