Work performed from the beginning of the project to the end of the period covered by the report and main results achieved so far (For the final period please include an overview of the results and their exploitation and dissemination)
Since the beginning of the project, the work realized can be classified in the following classes:
1- Demonstrating the onset of a lasing action in a benzene-like polaritonic molecule. This has allowed generating a coherent emission from a state that carries a well-defined topological charge. Furthermore, by using a circularly-polarized laser pump, it was possible to optically break time-reversal symmetry in a well-defined manner and control the chirality of the emission field, see image 1 attached. This is in line with the first objectvie described above, and has led to the following publication: Nat. Photonics 13, 283–288 (2019).
2- Using the device fabricated in the previous point, we were able to explore the nonlinear regime by working at high driving power. Thanks to gain saturation, we were able to observe a bistable regime between two modes carrying a distinct topological charge. This was the first observation of such a nonlinear effect with chiral light, and it is in line with the second objective described above. It has led to the following publication: Opt. Letters 44, 18, 4531-4534 (2019)
3- Recently, I have collaborated with a PhD student to observe nonlinear effects in topological arrays of higher dimensionality. Namely, we have demonstrated the onset of symmetry-protected solitons in a 1D topological lattice. This is also an important result in relation with the second objective. A manuscript is right now finalized, and should be submitted shortly to a high-impact journal.
4- In order to push the exploration of this physics in 2-dimension lattices, I have realized an important work where we have measured topological invariants in a honeycomb lattice that emulates the physics graphene, see image 2 attached. This is very relevant, as a similar lattice will be used to demonstrate (under a magnetic field) 2-dimensional topological lattices that break time-reversal symmetry. A manuscript has been updated on arXiv (2002.09528) and is currently under revision in a high-impact journal.