Scientific progress and potential impact:
The outcome of this project is the paper "Universality for outliers in weakly confined Coulomb-type systems", made in collaboration with David Garcia-Zelada, Alon Nishry and Aron Wennman. In the paper, we discover a new behavior for the particles of a Coulomb gas outside the support of the equilibrium measure. For a specific class of Coulomb gases, called jellium, we show that the outliers are described by a new universal process called the Bergman process. In addition, we also establish this behavior for zeros of random polynomials. This is a success for this research project as the goal was to obtain new results by comparing Coulomb gases and zeros of random polynomials. In this paper, we develop, in the case of Coulomb gases, a new technique to study the asymptotic properties of orthogonal polynomials in dimension 2, and techniques to understand reproducing kernels associated to orthogonal polynomials. In addition, we later realized that this techniques could be adapted to zeros of random polynomials.
I hope that this result will lead to many other interesting research projects in the same field, as it opens many new perspectives for both Coulomb gases and random polynomials. In the Coulomb gas litterature, the outliers were usually not studied and the focus was made on outliers-free systems. Now, outliers can be understood and studied for their own interest.
Socio economic impact:
The results of this project deal with high energy statistical physics. In theory, there exist physical systems which can be build to observe the results of this project. Unfortunately, it is highly unrealistic to expect a physical realization of these systems: the amount of electric energy needed to observe the results of this project is exponential with the number of particles and would require unreasonable amounts of energy.
The results of this project are part of a broad scientific trend, with the growing interest of the understanding of outliers in many particles systems (random matrices, coulomb gases, random polynomials), and asymptotic properties of zeros of random polynomials in signal processing. The results obtained here may not be directly used in applied problems, but I am convinced that the techniques that we developed will diffuse and influence other researchers in the areas mentionned previously.