Ten-valley excitonic complexes in charge-tunable monolayer WSe$_2$ (2505.08923v1)

Abstract: The optical response of two-dimensional (2D) semiconductors such as monolayer WSe$_2$ is dominated by excitons. Enhanced interactions result in the formation of many-body excitonic complexes, which provide a testing ground for excitons and quantum many-body theories. In particular, correlated many-body excitonic complexes could constitute a limiting case that puts competing exciton descriptions to the test. Here, we report a hitherto unobserved many-body excitonic complex that emerges upon electrostatically doping both the $K$ and $Q$ valleys with charge carriers. We optically probe the WSe$_2$ exciton landscape using charge-tunable devices with unusually thin gate dielectrics that facilitate doping up to several $10^{13}$ cm$^{-2}$. In this previously unexplored regime, we observe the emergence of the thermodynamically stable state in the presence of as many as 10 filled valleys. We gain insight into the physics of this complex using magneto-optical measurements. Our results are well-described by a model where the behavior of the formed exciton complex depends on the number of distinguishable Fermi seas with which the photoexcited electron-hole pair interacts. In addition to expanding the repertoire of excitons in 2D semiconductors, the extremal nature of this complex could probe the limit of exciton models and could help answer open questions about the screened Coulomb interaction in low-dimensional semiconductors.