Improving data transmission across computer networks is key to advancing the performance of modern data centers and massively parallelized supercomputers. Optical fibers provide outstanding transmission bandwidth, but light propagates 31% slower in a silica glass fiber than in vacuum, thus introducing a time delay. Air guidance in hollow-core fibers can improve this significantly, but it has proven challenging to achieve the combined values of loss, bandwidth and mode-coupling characteristics required for high-capacity data transmission.
Addressing this challenge, F. Poletti and colleagues from the University of Southampton have now fabricated hollow-core photonic-bandgap fibers (HC-PBGFs) that are capable of achieving both low surface scattering loss and wide surface-mode-free transmission bandwidth simultaneously (see Figure). This represents the first demonstration of fiber-based wavelength division multiplexed data transmission at close to (99.7%) the speed of light in a vacuum.
As reported in the April issue of Nature Photonics (DOI: 10.1038/nphoton.2013.45; p. 279), the team investigated the origin of the observed loss by developing a model of surface scattering in hollow fibers and performing simulations to predict the total loss. This showed that the surface-scattering contribution dominates at the center of the bandgap while confinement loss only reshapes its edges. To gain insight into the modal behavior of HC-PBGFs, the researchers used a combination of time-of-flight (TOF) and self-interferometric measurements (S2). When the fiber is excited with an offset launch, light is efficiently coupled into several high-order modes. Their lower group velocities relative to the fundamental mode then generate clearly resolvable delayed peaks in the TOF measurement. By cross-comparing results from the TOF and S2 measurements, the team was also able to identify all expected modes up to LP31. This was attributed to selective excitation of individual polarization modes within a mode group, and the high extinction ratios to relatively low intermodal crosstalk.
The results demonstrate an important step toward the viability of using HC-PBGFs for low-latency data transmission. The achieved loss values are adequate for low latency application, for example, in realization of next-generation peta-to-exaflop scale supercomputers and mega data centers.