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.

Time-of-flight experimental setup, where light is launched into 260 m of hollow-core photonic-bandgap fibers (HC-PBGFs) with a 12 mm laterally offset, butt-coupled (BC) standard single-mode fiber. Reproduced with permission from Nature Photon. 7 (2013), DOI: 10.1038/nphoton.2013.45; p. 279. © 2013 Macmillan Publishers Ltd.