Nonlinear dynamics of triple quantum dot molecules in a cavity: multi-stability of three types of cavity solitons

By numerical simulation of a cavity filled with triple quantum dot molecules under tunneling induced transparency, we show that various regimes of existence of different kinds of cavity solitons are possible. Forming in overlapping regions of a multistable parameter space, cavity solitons in this system exhibit different dynamical behaviors: stationary on a flat background when there is only one cavity soliton branch, oscillating when two cavity soliton branches coexist, and stationary-rambling on a honeycomb background arising from simultaneous presence of a stable pattern and a cavity soliton branch. In particular, we show that three different types of dissipative localized structures can be excited in multistable regions where material coherence is high due to light-matter interaction processes.

Automated summary

Numerical simulation demonstrates the existence of different dynamical behaviors of cavity solitons in a cavity filled with triple quantum dot molecules, including stationary, oscillating, and stationary-rambling states. Additionally, three different types of dissipative localized structures can be excited in regions with high material coherence due to strong light-matter interaction processes.