Large Rabi splitting obtained in Ag-WS2 strong-coupling heterostructure with optical microcavity at room temperature

Large Rabi splitting obtained in Ag-WS2 strong-coupling heterostructure with optical microcavity at room temperature

Manipulation of light-matter interaction is critical in modern physics, especially in the strong coupling regime, where the generated half-light, half-matter bosonic quasiparticles as polaritons are important for fundamental quantum science and applications of optoelectronics and nonlinear optics. T...

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Autores principales: Li Bowen, Zu Shuai, Zhang Zhepeng, Zheng Liheng, Jiang Qiao, Du Bowen, Luo Yang, Gong Yongji, Zhang Yanfeng, Lin Feng, Shen Bo, Zhu Xing, Ajayan Pulickel M., Fang Zheyu
Formato: article
Lenguaje:EN
Publicado: Institue of Optics and Electronics, Chinese Academy of Sciences 2019
Materias:
rabi splitting
strong coupling
transition metal dichalcogenides
optical microcavity
surface plasmons
Optics. Light
QC350-467
Acceso en línea:https://doaj.org/article/de1078c8730049aaac3f1a99f31591b6
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Sumario:Manipulation of light-matter interaction is critical in modern physics, especially in the strong coupling regime, where the generated half-light, half-matter bosonic quasiparticles as polaritons are important for fundamental quantum science and applications of optoelectronics and nonlinear optics. Two-dimensional transition metal dichalcogenides (TMDs) are ideal platforms to investigate the strong coupling because of their huge exciton binding energy and large absorption coefficients. Further studies on strong exciton-plasmon coupling by combining TMDs with metallic nanostructures have generated broad interests in recent years. However, because of the huge plasmon radiative damping, the observation of strong coupling is significantly limited at room temperature. Here, we demonstrate that a large Rabi splitting (~300 meV) can be achieved at ambient conditions in the strong coupling regime by embedding Ag-WS2 heterostructure in an optical microcavity. The generated quasiparticle with part-plasmon, part-exciton and part-light is analyzed with Hopfield coefficients that are calculated by using three-coupled oscillator model. The resulted plasmon-exciton polaritonic hybrid states can efficiently enlarge the obtained Rabi splitting, which paves the way for the practical applications of polaritonic devices based on ultrathin materials.

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