Bismuth-doped fibre amplifiers for extended transmission bands in optical communications

Global internet traffic has grown exponentially over the past 2 decades with a predicted growth rate of around 40% year on year. This growth is driven primarily by bandwidth-hungry applications such as cloud computing, Telemedicine, 4K live streaming. Growth is expected to continue in the era of the Internet of Things (IoT) and 5G. 

The present optical fibre communication network’s capacity is solely based on the 11THz (C and L bands) gain bandwidth of erbium (Er) doped fibre amplifiers (EDFA) invented 3 decades ago. The scaling of the overall transmission capacity requires next-generation optical fibre amplifiers to further utilise the low-loss window offered by solid- and hollow-core silica optical fibres.

In this project, we aim to develop efficient Bi-doped fibres and to demonstrate next-generation ultra-broadband Bi-doped fibre amplifiers (BDFAs) covering the wavelength regions of 1250-1500nm and 1600-1750nm. In the process of developing Bi-doped fibres, You'll also study spectroscopic properties such as absorption and emission cross-sections to understand the near-IR luminescence in these fibres. 

The focus will be on experimental work, but can include simulations and modelling of new amplifiers based on your interests. You'll have access to state-of-the-art fibre fabrication facilities and laboratories at the Optoelectronics Research Centre (ORC). The performance of developed BDFAs will be evaluated in collaboration with our academic partners.

Our research demonstrating a record level of optical gain (40dB), a wide amplification bandwidth (>120nm), and the highest reported gain per unit length (1.42 dB/m from BDFAs has been widely recognised by the scientific community and has attracted considerable attention from the telecommunications and related industries.