Resonant Bragg quantum wells in hybrid photonic crystals: optical properties and applications

The exciton-polariton propagation in resonant hybrid periodic stacks of isotropic/anisotropic layers, with misaligned in-plane anisotropy and Bragg photon frequency in resonance with Wannier exciton of 2D quantum wells is studied by self-consistent theory and in the effective mass approximation. The optical tailoring of this new class of resonant Bragg reflectors, where the structural periodicity of a multi-layer drives the in-plane optical $\hat{C}$-axis orientation, is computed for symmetric and asymmetric elementary cells by conserving strong radiation-matter coupling and photonic band-gaps. The optical response computation, on a finite cluster of N-asymmetric elementary cells, shows anomalous exciton-polariton propagation and absorbance properties strongly dependent on the incident wave polarizations. Finally, the behaviour of the so-called intermediate dispersion curves, close to the unperturbed exciton resonance, and located between upper and lower branches of the first band gap, is studied as a function of the in-plane $\hat{C}$-axis orientation. This latter optical property is promising for storing exciton-polariton impulses in this kind of Bragg reflector.