English

Hot biexcitons driven by extreme optical confinement

Optics 2026-05-11 v1 Materials Science

Abstract

A powerful means to understanding condensed matter that possesses a multi-constituent, non-isolated, and complex nature, with a preeminent example being two-dimensional (2D) materials, is studying many-body interactions. However, experimentally observing high-order many-body interactions is a daunting task due to its heavy reliance on the abundance of low-order complexes. Here, we report the observation of four-body hot biexcitons in an energetically unfavorable bilayer of tungsten disulfide (WS2) through creating extreme optical confinement. Specifically, we integrate a non-radiative bound state in the continuum (BIC) into a photonic crystal (PhC) defect cavity, forming a quasi-three-dimensional (q-3D) but open confinement for photons at the driving frequency. The extremely confined photons in both reciprocal and physical spaces then excite inherently unproductive two-body hot excitons situated slightly above the indirect bandgap so efficiently that they form overwhelmed higher-order four-body hot biexcitons. Distinctively, these hot biexcitons exhibit substantial valley polarization and coherence at room temperature, which we attribute to the topological nature of BICs and the associated q-3D confinement with an orbital angular momentum. Besides achieving room-temperature biexcitons, the q-3D confinement could be valuable for higher-order interactions, such as triexcitons, and many other many-body phenomena, including Bose-Einstein condensation.

Keywords

Cite

@article{arxiv.2605.08041,
  title  = {Hot biexcitons driven by extreme optical confinement},
  author = {Xinyi Wang and Kaushik Kudtarkar and Wenjing Wu and Yunjo Jeong and Yuxuan Cosmi Lin and Xiaofeng Qian and Junichiro Kono and Shengxi Huang and Shoufeng Lan},
  journal= {arXiv preprint arXiv:2605.08041},
  year   = {2026}
}
R2 v1 2026-07-01T12:58:15.869Z