Effective Refractive-Index Approximation: A Link between Structural and Optical Disorder of Planar Resonant Optical Structures

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Date
2018-06-27
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Physical Review Applied
Volume Title
9
Article Title
064041
Publisher
American Physical Society
Abstract
We provide detailed insights into a link between structural and optical disorder of resonant optical structures, in particular, distributed Bragg reflectors (DBRs) and resonant microcavities (μCs). The standard (targeted) DBR structures have periodic square-wave-like refractive-index profiles, and their optical performance is determined by the refractive-index ratio of the two applied materials (n12=n1/n2, n1>n2) and the number of DBR periods (N). It is well known that its structural disorder strongly affects its optical properties, but, despite that, this influence has not been quantitatively addressed in the literature. We propose a precise quantitative definition for a structural disorder of a single DBR unit cell (disorder factor DF), completing the set of DBR fundamental parameters (n12, N, DF). Then we expose the basis for the effective refractive-index approximation (ERIA), showing that, as long as DBR optical properties are concerned, the influence of increasing structural disorder (DF↑) is virtually identical to the influence of decreasing refractive-index ratio (n12↓), with the latter influence being easily quantified. Making use of the ERIA method, simple analytical formulas, which enable rapid insights into the reflectivity and stop-band width of DBRs with different types of transient layers at the heterointerfaces, are derived and the results validated, via both transfer-matrix simulations and direct experimental measurements of imperfect DBRs. The insights of the ERIA method are then further applied on resonant μCs, providing a comprehensive link between their structural disorder and subsequent deterioration of their quality (Q) factor.
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