| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 1543333 | Photonics and Nanostructures - Fundamentals and Applications | 2012 | 9 Pages |
We have recently developed a simple phenomenological model that allows one to account for the modifications of the gain characteristics of nanocomposite optical materials with specific geometries. Here we give a generalized formulation of our model to show that it can be applied to a broad variety of composite geometries. We demonstrate the application of our model using the Maxwell Garnett composite geometry with the resonant molecules in its host, which represent a practically important case that has not been treated earlier. We also give numerical examples for the Maxwell Garnett composite geometry with the resonances in either host or inclusions, and find the conditions under which it is possible to achieve an enhancement or suppression of the small-signal gain coefficient compared to its value in a bulk material. Using our simple model, one can identify the set of parameters, exhibiting the desired changes to the gain characteristics, prior to or instead of performing a more precise computationally intensive analysis.
► We consider the small-signal gain in all-dielectric composite materials. ► We present simple model that can be applied to an arbitrary composite geometry. ► The model can be used to estimate the small-signal gain coefficient. ► We apply our model to the case of Maxwell Garnett composite material.
