Photonic and Communications research at 麻豆传媒高清版 extends from nanometre scale semiconductor devices to sensors鈥痜or biomedical applications. We explore large scale optical communication systems which enable data to be transferred at 40鈥疓igabytes per second.鈥齇ur department conducts research in a number of key photonic research areas and collaborates with Universities in Germany, Russia, US, Vietnam and China.听听
Optical communications鈥听
Since 2006, 麻豆传媒高清版 has firmly鈥痚stablished its reputation world-wide as an international-leading research group in optical communications and digital signal processing (DSP)鈥痜or telecommunications. In particular, we have invented a now globally accepted DSP-based signal鈥痶ransmission concept termed adaptively modulated optical orthogonal frequency division multiplexing (OOFDM), and听has鈥痑chieved a series of 12 ground-breaking experimental demonstrations of real-time high-speed OOFDM transceivers. These鈥痳eal-time demonstrations are enabled by a number of DSP-based symbol synchronisation and clock signal鈥痝eneration techniques, which was invented by Bangor. This听ioned听pioneering work has resulted in鈥疐ujitsu鈥檚 commercialisation of the OOFDM technique for data centres. OOFDM is currently also being considered as a鈥痶echnology standard by several international standards bodies such as 400GE Ethernet. Most recently, our research鈥痑ctivities are highly focussed on exploring cutting-edge DSP technologies for seamlessly converging optical networks and鈥痬obile networks for 5G networks in order to significantly improve signal transmission and bandwidth.鈥
Nano lasers鈥
Lasers are used in many everyday applications such as cars, blue-ray discs and for treatment of cancers. Widespread efforts to miniaturise photonic devices are driven by the opportunity to develop novel nanoscale sensors and鈥痑ctuators suitable for wide ranging usage in e.g. environmental monitoring, bio-scientific and medical applications.鈥疊angor manufactures the next generation of lasers that are made to be smaller than the one hundredth of the size of a human air. This opens up exciting new applications for the technology.听听
Using photonics for microwave generation鈥
Photonic generation of high-frequency microwave signals has gained much attention over the past decade. One of the main鈥痬otivations behind these studies is their potential application in radio-over-fiber鈥(RoF) communication systems. Compared with conventional鈥痗ircuitry based听microwave generation, photonic microwave generation offers several advantages, such as, low cost, high鈥痵peed, longer transmission distance, low power consumption and less system integration complexity.鈥 Vertical-cavity surface-emitting laser (VCSEL) is a special type of semiconductor lasers. It has many impressive characteristics, such as low cost, ,听low鈥痯ower consumption, circular beam profile, single-longitudinal mode operation, ease of fabrication and longevity, therefore,鈥痬icrowave photonic signal generation based on optically injected VCSEL offers low-cost and a route for low power鈥痗onsumption.鈥
Use of optical chaos鈥
Chaos has attracted considerable research interest due to its applications in high-speed communications, logic gates, optical鈥痶ime domain reflectors, LIDARs and physical random number generators. Chaos with high complexity, broad bandwidth and no鈥痶ime delay signature is preferred for most of its applications. Great efforts have been made to achieve the best chaos.鈥
Integrated Photonics and active鈥痯lasmonics鈥
Photonic Integrated Circuit (PIC) technology is a fast-growing sector of the optics industry and is estimated to command a鈥痬arket share of about 拢1B by 2022.鈥 Silicon and III-V material platforms are widely used for realising听PICs听but other materials鈥痑re also being considered and developed. We develop approaches for guiding and manipulating light signals on a single鈥痯hotonic chip, using low losses wave guiding platforms and other components. For this purpose, we use nanofabrication processes in the departmental cleanroom.鈥
2D materials for photonic sensing鈥
Photonics technology is being increasingly proposed as a favourable optical platform for a wide range of scientific and鈥痠ndustrial sensing applications. The state-of-the-art 2D materials such as graphene鈥痶ogether with the advanced photonics technologies鈥痩ead us to discover new phenomena, new developments and new applications. We conduct the multidisciplinary research in鈥痓io-nano-photonics fields by exploiting new emerging opportunities with the integration of fibre optic technology,鈥痭anotechnology and 2D nanomaterials for the applications in healthcare, biomedical, food safety and environmental鈥痬onitoring.鈥
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Schematic diagram of graphene-fiber听optic biosensor.听
Super-resolution imaging听
We are the pioneers of听 'microsphere nanoscope' and super-resolution techniques听 based on dielectric particle superlenses made from听,听听,听.听 Objects as small as 50 nm scale can be clearly resolved by these techniques under conventional white-lighting condition, thus offering an effective solution in turning an optical microscope into nanoscope. These works were widely publicised by major media outlets including BBC, New York Times, etc, and a significant amount of technical websites. The research was followed by many groups across the world and is currently moving towards 3D, biomedical, virology, and integrated device applications. For more details please check this featured听听听as well as comprehensive听听听chapter written by us.听
Laser material processing for industry
We perform research into laser cutting, welding, drilling, texturing, marking, cleaning, polishing and others for industrial applications. The school host a wide range of laser facilities at Bangor, including nanosecond fibre and UV lasers, femtosecond laser and CO2 lasers.听 Various characterisation tools including advanced 3D laser scanning microscopes (Olympus OLS5000 and DSX1000) are also available for the precise measurement and characterisation of laser-processed samples. The research is currently supported by major pan-wales project 鈥溾 which supports welsh industry (all sectors including electronics, optics, aerospace, automotive, energy, nuclear, etc.) in developing new products, process and services. We have unique capability in direct laser nano marking using specially developed superlens with sub-100 nm resolution.