The digital era has witnessed an unprecedented growth in data transfer and processing. As emerging technologies like quantum communications, neural networks, and high-capacity networks continue to evolve, there is an increasing demand for larger bandwidths and higher data transfer speeds. To achieve these requirements, researchers have explored the use of optical interconnects as a potential solution. By replacing traditional metallic wires with light-based channels for data transfer, optical interconnections offer the promise of incredibly high speeds through mode-division multiplexing (MDM).

However, despite the potential benefits of optical interconnects, the speed of MDM systems reported in the past has been limited. One of the main challenges lies in the imperfections of device fabrication, which often result in refractive index variations of the waveguides. These imperfections can adversely impact the performance of MDM systems. To overcome this limitation, researchers have focused on engineering the refractive indices of waveguides through structure and composition optimization. Unfortunately, current methods are constrained by either material limitations or large circuit footprints.

In light of these challenges, Professor Yikai Su and his team from Shanghai Jiao Tong University in China embarked on a research endeavor to develop a novel approach for coupling different light modes in MDM systems. Published in Advanced Photonics, their study highlights an innovative design for a light-mode coupler that can manipulate specific light modes traveling in a nearby bus waveguide. This coupler has the ability to inject or extract light modes from the bus waveguide, redirecting them to different paths.

To achieve high coupling coefficients and mitigate the impact of fabrication errors, the researchers utilized a gradient-index metamaterial (GIM) waveguide. Unlike conventional materials, the GIM exhibits a continuously varying refractive index along the direction of light propagation. This unique characteristic enables seamless and efficient transition of individual light modes to and from the nanowire bus, compensating for parameter variations in the waveguides.

By cascading multiple couplers, the research team successfully implemented a 16-channel MDM communication system, supporting 16 different light modes simultaneously. In a data transmission experiment, this system achieved an unprecedented data transfer rate of 2.162 Tbit/s, setting a new record for on-chip devices operating at a single wavelength. Furthermore, the researchers employed fabrication methods compatible with semiconductor device fabrication, making the design scalable and compatible with existing technology.

This breakthrough coupling strategy using GIM structures has the potential to revolutionize data rates, particularly in fields that heavily rely on parallel data transmissions and computations. By enabling high-speed data transfer, optical interconnects could pave the way for advancements in hardware acceleration, large-scale neural networks, and quantum communications.

Rapid advancements in technology have necessitated the development of high-speed data transfer solutions. Optical interconnects, with their potential for mode-division multiplexing, offer a promising avenue for achieving the desired bandwidth and data transfer speeds. Overcoming fabrication imperfections in MDM systems has been a key challenge, which researchers are tackling through innovative approaches like the one developed by Professor Su and his team. By leveraging gradient-index metamaterials, they have achieved record-breaking data rates, opening new possibilities for hardware acceleration and communication systems. As technology continues to evolve, the potential of optical interconnects for high-speed data transfer is increasingly becoming a reality.

Science

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