Interband cascade technology for energy-efficient mid-infrared free-space communication

Space-to-ground high-speed transmission is of utmost importance for the development of a worldwide broadband network. Mid-infrared wavelengths offer numerous advantages for building such a system, spanning from low atmospheric attenuation to eye-safe operation and resistance to inclement weather conditions. We demonstrate a full interband cascade system for high-speed transmission around a wavelength of 4.18 mu m. The low-power con-sumption of both the laser and the detector in combination with a large modulation bandwidth and sufficient output power makes this technology ideal for a free-space optical communication application. Our proof-of -con-cept experiment employs a radio-frequency optimized Fabry-Perot interband cascade laser and an interband cascade infrared photodetector based on a type-II InAs/GaSb superlattice. The bandwidth of the system is evaluated to be around 1.5 GHz. It allows us to achieve data rates of 12 Gbit/s with an on-off keying scheme and 14 Gbit/s with a 4-level pulse amplitude modulation scheme. The quality of the transmission is enhanced by conventional pre-and post-processing in order to be compatible with standard error-code correction.(c) 2023 Chinese Laser Press

Automated summary

Space-to-ground high-speed transmission is crucial for global broadband network development. The use of mid-infrared wavelengths offers advantages like low atmospheric attenuation and resistance to inclement weather conditions. A proof-of-concept experiment demonstrates a full interband cascade system that achieves high-speed transmission around a wavelength of 4.18 μm.