CHINESE ACADEMY OF SCIENCES

The Rydberg state is widely present in a variety of physical platforms such as atoms, molecules, and solids. In particular, Rydberg excitons are highly excited Coulomb bound states of electron-hole pairs, first discovered in the semiconductor material Cu2O in the 1950s. Their solid-state nature, in conjunction with their large dipole moments, strong mutual interactions, and significantly enhanced interactions with the surroundings, holds promise for a wide range of applications in sensing, quantum optics, and quantum simulation. However, compared to that of their atomic counterparts, Rydberg atoms, that have been widely explored in recent years, the exploitation of Rydberg excitons is far from reaching its full potential. One of the main obstacles lies in the difficulty of realizing efficient trapping and manipulation of the Rydberg excitons. Lately, the rise of two-dimensional moiré superlattices with highly tunable periodic potentials provides a possible pathway.

A cartoon showing the Rydberg moiré excitons in the WSe2/TBG heterostructure [IMAGE: IOP]

In recent years, researchers from the Institute of Physics (IOP) of the Chinese Academy of Sciences including Dr. Xu Yang and his collaborators have been devoted to exploring the application of Rydberg excitons in two-dimensional (2D) semiconducting transition metal dichalcogenides (such as WSe2). They have developed a new Rydberg sensing technique that utilizes the sensitivity to the dielectric environment of the Rydberg excitons to detect the exotic phases in a nearby 2D electronic system. For example, using this technique, they have been able to reveal the abundance of correlated insulating states at fractional fillings in a 2D moiré heterobilayer platform (WSe2/WS2). Recently, they have collaborated with a team led by Dr. Yuan Shengjun from Wuhan University and reported the observation of Rydberg moiré excitons, which are moiré trapped Rydberg excitons in monolayer semiconductor WSe2 adjacent to small-angle twisted bilayer graphene (TBG).

Spectroscopic evidence of the Rydberg moiré exciton formation in WSe2 adjacent to 0.6° TBG and numerical calculations of the spatial charge distribution in TBG at different doping levels [IMAGE: IOP]

Through low-temperature optical spectroscopy measurements, they first find the Rydberg moiré excitons manifest as multiple energy splittings, pronounced red shift, and narrowed linewidth in the reflectance spectra. By comparing them with numerical calculations performed by the group from Wuhan University, they attribute these observations to the spatially varying charge distribution in TBG, which creates a periodic potential landscape (so-called moiré potential) for interacting with the Rydberg excitons. The strong confinement of the Rydberg exciton is achieved through the largely unequal interlayer interactions for the constituent electron and hole of the Rydberg exciton by the spatially accumulated charges centered in the AA-stacked regions of TBG. The Rydberg moiré excitons hence realize electron-hole separation and exhibit the character of long-lived charge-transfer excitons.

Twist angle dependences and crossover to the strong-coupling regime [IMAGE: IOP]

They demonstrate a novel method of manipulating Rydberg excitons that can be hardly achieved in bulk semiconductors. The long-wavelength (tens of nm) moiré superlattice here renders an analogue to the optical lattices created by a standing-wave laser beam or arrays of optical tweezers for Rydberg atom trapping. The tunable moiré wavelengths, the in-situ electrostatic gating, and longer lifetime ensure great controllability of the system, with a strong light-matter interaction for convenient optical excitation and readout. Our study could bring up new opportunities for the next-step realization of the Rydberg-Rydberg interactions and coherent control of the Rydberg states for further application in quantum information processing and quantum computation.

This study entitled “Observation of Rydberg moiré excitons” was published in Science.

For more information, please contact:

Xu Yang

E-mail: yang.xu@iphy.ac.cn

Institute of Physics,

Chinese Academy of Sciences

Source: Institute of Physics,

Chinese Academy of Sciences

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