| Literature DB >> 30860854 |
Shao-Yu Chen1, Zhengguang Lu2,3, Thomas Goldstein1, Jiayue Tong1, Andrey Chaves4, Jens Kunstmann5, L S R Cavalcante4, Tomasz Woźniak5,6, Gotthard Seifert5, D R Reichman7, Takashi Taniguchi8, Kenji Watanabe8, Dmitry Smirnov2, Jun Yan1.
Abstract
We report the experimental observation of radiative recombination from Rydberg excitons in a two-dimensional semiconductor, monolayer WSe2, encapsulated in hexagonal boron nitride. Excitonic emission up to the 4 s excited state is directly observed in photoluminescence spectroscopy in an out-of-plane magnetic field up to 31 T. We confirm the progressively larger exciton size for higher energy excited states through diamagnetic shift measurements. This also enables us to estimate the 1 s exciton binding energy to be about 170 meV, which is significantly smaller than most previous reports. The Zeeman shift of the 1 s to 3 s states, from both luminescence and absorption measurements, exhibits a monotonic increase of the g-factor, reflecting nontrivial magnetic-dipole-moment differences between ground and excited exciton states. This systematic evolution of magnetic dipole moments is theoretically explained from the spreading of the Rydberg states in momentum space.Entities:
Keywords: Rydberg exciton; Zeeman shift; diamagnetic shift; magnetic dipole moment; tungsten diselenide
Year: 2019 PMID: 30860854 DOI: 10.1021/acs.nanolett.9b00029
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189