Gain-assisted critical coupling for enhanced optical absorption in graphene

Enhanced optical absorption in two-dimensional (2D) materials has recently moved into the focus of nanophotonics research. In this work, we present a gain-assisted method to achieve critical coupling and demonstrate the maximum absorption in undoped monolayer graphene in the near-infrared. In a two-port system composed of photonic crystal slab loaded with graphene, the gain medium is introduced to adjust the dissipative rate to match the radiation rate for the critical coupling, which is accessible without changing the original structural geometry. The appropriate tuning of the gain coefficient also enables the critical coupling absorption within a wide wavelength regime for different coupling configurations. This work provides a powerful guide to manipulate light-matter interaction in 2D materials and opens up a new path to design ultra-compact and high-performance 2D material optical devices.

Automated summary

This work presents a gain-assisted method to achieve critical coupling and demonstrate maximum absorption in undoped monolayer graphene in the near-infrared. By introducing a gain medium, the dissipative rate is adjusted to match the radiation rate for achieving critical coupling, without changing the original structural geometry. The appropriate tuning of the gain coefficient also enables critical coupling absorption within a wide wavelength regime for different coupling configurations.