The composite polarization of multicomponent III-nitride for component nanostructures
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Abstract
The structural and technological polarization aspects of multicomponent solid solutions of A3B5 compounds, particularly III-nitride, have been considered. It is shown that in the lattices of binary compounds of various sizes, ionic and electronic nanostructures, the atom substitutions cause local electric fields and different potential barriers, which can be clustered with a predominant directed electric field vectors. From the standpoint of the energy storage media, a comparative analysis of polarization in multicomponent solid solutions of semiconductors and ferroelectrics has been carried out. Multi-component solid solutions of A3B5 semiconductors for the first time treated as unordered system of atoms, unlike the orderly crystalline distribution with translational invariance and symmetry. Solid solutions based on heterogeneous quaternary structure (AlInNSb and BInNSb) have been proposed for new promising radiating systems with possibility of energy conversion and accumulation.
Byblos. 20, Fig. 5.
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