The first part of the project has been dedicated to the development of a numerical platform, which has been implemented in the form of a software toolbox with files written in Matlab and Mathematica languages. This toolbox allows one to simulate the propagation of, and interaction among, many modes in MM- and MC fibers, as well as to design MM/MC fiber-based devices (e.g. amplifiers and lasers) and to predict their performance. This platform has been widely used through the whole project.
The initial numerical investigation led to a new understanding of the nonlinear multimode dynamics and to major results.
First of all, the observation and comprehension of long-haul vector soliton data transmission, which is based on the nonlinear interaction among 2 polarization modes of an optical fiber. These numerical results have been obtained in collaboration with the group of Dr. J.Fatome at the University of Bourgogne, and have found full confirmation in experiments led by Dr.Fatome. These outcomes, which gained the cover of the prestigious journal Nature Photonics (Vol.11,Issue 2,Feb 2017, https://www.nature.com/nphoton/volumes/11/issues/2 ), demonstrate that multimode nonlinear interactions can be exploited to achieve almost undistorted data transmission, which may strongly reduce the power consumption and complexity of the current Internet network.
The project has also allowed developing novel fundamental ideas for the design of broadband MM parametric amplifiers and oscillators, which have led to the first experimental implementation of a fiber-based wavelength converter of several different modes. These results represent an important step towards a new generation of efficient all-optical devices that may be essential key-technology in the Internet network of the future.
Finally, the project has allowed modelling and running some preliminary numerical simulations that clearly show a novel, robust mechanism to achieve coherent beam combination in MC fiber lasers. These simulations show that nonlinearity may induce a strong coupling between the modes in different cores, such that the light beams in each core organize themselves in regular patterns. Under proper conditions, the beams may add in phase in a single core, giving rise to a single “giant” beam characterized by an extremely high power density.