AI Article Synopsis
- Ternary III-nitride nanowires (NWs) show potential for optoelectronic devices due to precise control over their design, structure, and strain.
- Using scanning transmission electron microscopy, the study found atomic-level chemical ordering in wurtzite InGaN alloys, confirming nonrandom c-plane occupation and indicating a unique arrangement of In-rich and Ga-rich planes.
- The research suggests that optimizing atomic ordering in these nanowires may enhance their structural and compositional properties, which could be beneficial for applications that work in the longer visible wavelengths.
Article Abstract
Ternary III-nitride based nanowires (NWs) are promising for optoelectronic applications by offering advantageous design and control over composition, structure, and strain. Atomic-level chemical ordering in wurtzite InGaN alloys along the c-plane direction with a 1:1 periodicity within InGaN/GaN NW heterostructures was investigated by scanning transmission electron microscopy. Atomic-number-sensitive imaging contrast was used to simultaneously assign the In-rich and Ga-rich planes and determine the crystal polarity to differentiate unique sublattice sites. The nonrandom occupation of the c-planes in the InGaN alloys is confirmed by the occurrence of additional superlattice spots in the diffraction pattern within the ternary alloy. Compositional modulations in the ordered InGaN was further studied using atomic-resolution elemental mapping, outlining the substantial In-enrichment. Confirming the preferential site occupation of In-atoms provides experimental validation for the previous theoretical model of ordered InGaN alloys in bulk epilayers based on differences in surface site energy. Therefore, this study strongly suggests that atomic ordering in InGaN has a surface energetics-induced origin. Optimization of atomic ordering, in particular in III-nitride NW heterostructures, could be an alternative design tool toward desirable structural and compositional properties for various device applications operating at longer visible wavelengths.
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| http://dx.doi.org/10.1021/acs.nanolett.5b01628 | DOI Listing |
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