Combining a tungsten disulfide monolayer and a topologically protected bound state in the continuum formed by a one-dimensional photonic crystal, strong light-matter interaction enhancement and large exciton-polariton nonlinearities at room temperature are demonstrated.Exciton-polaritons derived from the strong light-matter interaction of an optical bound state in the continuum with an excitonic resonance can inherit an ultralong radiative lifetime and significant nonlinearities, but their realization in two-dimensional semiconductors remains challenging at room temperature. Here we show strong light-matter interaction enhancement and large exciton-polariton nonlinearities at room temperature by coupling monolayer tungsten disulfide excitons to a topologically protected bound state in the continuum moulded by a one-dimensional photonic crystal, and optimizing for the electric-field strength at the monolayer position through Bloch surface wave confinement. By a structured optimization approach, the coupling with the active material is maximized here in a fully open architecture, allowing to achieve a 100 meV photonic bandgap with the bound state in the continuum in a local energy minimum and a Rabi splitting of 70 meV, which results in very high cooperativity. Our architecture paves the way to a class of polariton devices based on topologically protected and highly interacting bound states in the continuum.
Strongly enhanced light-matter coupling of monolayer WS2 from a bound state in the continuum / Maggiolini, Eugenio; Polimeno, Laura; Todisco, Francesco; Di Renzo, Anna; Han, Bo; De Giorgi, Milena; Ardizzone, Vincenzo; Schneider, Christian; Mastria, Rosanna; Cannavale, Alessandro; Pugliese, Marco; De Marco, Luisa; Rizzo, Aurora; Maiorano, Vincenzo; Gigli, Giuseppe; Gerace, Dario; Sanvitto, Daniele; Ballarini, Dario. - In: NATURE MATERIALS. - ISSN 1476-1122. - STAMPA. - 22:8(2023), pp. 964-969. [10.1038/s41563-023-01562-9]
Strongly enhanced light-matter coupling of monolayer WS2 from a bound state in the continuum
Cannavale, Alessandro;
2023-01-01
Abstract
Combining a tungsten disulfide monolayer and a topologically protected bound state in the continuum formed by a one-dimensional photonic crystal, strong light-matter interaction enhancement and large exciton-polariton nonlinearities at room temperature are demonstrated.Exciton-polaritons derived from the strong light-matter interaction of an optical bound state in the continuum with an excitonic resonance can inherit an ultralong radiative lifetime and significant nonlinearities, but their realization in two-dimensional semiconductors remains challenging at room temperature. Here we show strong light-matter interaction enhancement and large exciton-polariton nonlinearities at room temperature by coupling monolayer tungsten disulfide excitons to a topologically protected bound state in the continuum moulded by a one-dimensional photonic crystal, and optimizing for the electric-field strength at the monolayer position through Bloch surface wave confinement. By a structured optimization approach, the coupling with the active material is maximized here in a fully open architecture, allowing to achieve a 100 meV photonic bandgap with the bound state in the continuum in a local energy minimum and a Rabi splitting of 70 meV, which results in very high cooperativity. Our architecture paves the way to a class of polariton devices based on topologically protected and highly interacting bound states in the continuum.| File | Dimensione | Formato | |
|---|---|---|---|
|
2023_Strongly_enhanced_light–matter_coupling_of_monolayer_WS2_from_a_bound_state_in_the_continuum_firstonline.pdf
Solo utenti POLIBA
Tipologia:
Versione editoriale
Licenza:
Tutti i diritti riservati
Dimensione
1.43 MB
Formato
Adobe PDF
|
1.43 MB | Adobe PDF | Visualizza/Apri |
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
