We develop the theoretical and computational framework to understand, quantitatively describe, and control quantum transport phenomena in solids and liquids involving, e.g., charge, heat, light and spin, their possible synergies or conflicts, and related macroscopic signatures. The ambition is twofold: first, to evolve current materials for storage and management of information or energy, and second, to innovate on existing applications or even conceive new ones, in collaboration with experimentalists and industry.
Our technical interests revolve around transport equations for quantum excitations, techniques to coarse-grain atomistic formulations into continuum models or constitutive relations for device design, and the development of AI-driven methods to solve - with quantitative accuracy - problems ranging from the atomistic to the continuum scale.
We foster an inclusive, supportive, and innovative environment, where every member can reach their full potential and work on a mission greater than themselves.
