Highly Efficient Single-Exciton Strong Coupling with Plasmons by Lowering Critical Interaction Strength at an Exceptional Point

The single-exciton strong coupling with the localized plasmon mode (LPM) at room temperature is highly desirable for exploiting quantum technology. However, its realization has been a very low probability event due to the harsh critical conditions, severely compromising its application. Here, we present a highly efficient approach for achieving such a strong coupling by reducing the critical interaction strength at the exceptional point based upon the damping inhibition and matching of the coupled system, instead of enhancing the coupling strength to overcome the system's large damping. Experimentally, we compress the LPM's damping linewidth from about 45 nm to about 14 nm using a leaky Fabry-Perot cavity, a good match to the excitonic linewidth of about 10 nm. This method dramatically relaxes the harsh requirement in mode volume by more than an order of magnitude and allows a maximum direction angle of the exciton dipole relative to the mode field of up to around 71.9 degrees, significantly improving the success rate of achieving the single-exciton strong coupling with LPMs from about 1% to about 80%.

Automated summary

A highly efficient approach for achieving strong coupling between single excitons and localized plasmon modes at room temperature is presented. By reducing the critical interaction strength at the exceptional point, rather than enhancing the coupling strength, the researchers were able to overcome the system's large damping. Experimental results showed a significant improvement in the success rate of achieving strong coupling, from about 1% to about 80%.