In a groundbreaking advancement published recently, researchers have unveiled a novel on-chip nonlocal metasurface that remarkably overcomes the persistent efficiency losses caused by spatial multiplexing in color routing applications. This cutting-edge technology, detailed by Shi, Wan, Wang, and colleagues in Light: Science & Applications, represents a pivotal leap forward in integrated photonics, potentially revolutionizing how color information is manipulated and routed in compact optical devices.
Metasurfaces, ultra-thin planar structures engineered to manipulate electromagnetic waves precisely, have long been hailed as a transformative platform in optics and photonics. However, when applied to color routing—where different wavelengths corresponding to colors must be spatially separated and directed—conventional metasurfaces suffer from significant efficiency degradation. This is primarily due to spatial multiplexing, a method where multiple functionalities are merged into a single device by partitioning its surface into distinct regions, each responding to a specific color. While functionally useful, this approach inherently divides the available aperture and energy, leading to intrinsic losses and performance limitations.
The research team’s novel strategy leverages the concept of ‘nonlocal’ metasurfaces, which fundamentally diverge from the traditional ‘local’ phase control mechanism. Instead of manipulating light on a point-by-point basis with isolated meta-atoms, nonlocal metasurfaces exploit collective interactions across the entire structure to achieve wavefront shaping with higher efficiency and multifunctionality. This approach preserves the total optical aperture for each color channel, circumventing the classical trade-off between multiplexing and efficiency.
At the heart of this innovation lies a meticulously engineered metasurface design that integrates resonant modes capable of spatially separating red, green, and blue light components without splitting the device area. By controlling the interplay of light within this engineered surface, the device can route each color component to different output ports with minimal losses. This significant enhancement stems from the intrinsic wave interactions engineered through the metasurface’s nonlocal resonances, which contrast sharply with the conventional local responses.
The implications of this advancement are profound. In integrated photonic circuits, efficient color routing is essential for applications ranging from optical communications and imaging systems to augmented reality and display technologies. Traditional spatial multiplexing metasurfaces forced a compromise between device size, efficiency, and color channel isolation, which hindered practical deployment in compact and high-performance systems. The nonlocal metasurface developed here breaks this trade-off by delivering unprecedented efficiency without increasing device complexity or footprint.
In their experimental demonstration, the researchers achieved near-unity efficiency in routing visible colors, marking a staggering improvement over previously reported metasurface-based color routers. This level of efficiency is crucial for real-world applications, where energy constraints and signal integrity define device feasibility. The ability to route multiple colors on a single chip with minimal crosstalk and energy loss presents new avenues for integrated photonics designs that demand precise spectral control.
The theoretical underpinnings of the device were corroborated with rigorous numerical simulations and experimental validations. The team employed advanced electromagnetic modeling techniques to design the nonlocal metasurface such that the tailored resonances selectively couple to different spectral bands. This engineered spectral selectivity, combined with spatial routing properties, constitutes a new paradigm in metasurface design.
Crucially, this work challenges a longstanding benchmark in metasurface research: the trade-off between multiplexing capacity and optical efficiency. By harnessing collective resonant behaviors that extend beyond local interactions, the researchers demonstrate that multifunctional metasurfaces can achieve high performance without the conventional penalties associated with spatial segmentation. This conceptual breakthrough signals new opportunities for designing metasurfaces that manage multiple degrees of freedom simultaneously.
The practical advantages of such an efficient color router extend into photonic integrated circuits where space is at a premium, and component integration density must be maximized. Devices benefiting from this technology could see substantial improvements in size, energy consumption, and bandwidth, addressing key challenges in developing next-generation optical interconnects for data centers, high-resolution displays, and advanced sensing platforms.
Beyond applications, this research contributes substantially to the fundamental understanding of light-matter interaction in artificially structured media. By demonstrating a nonlocal approach practically, the work expands the theoretical landscape of metasurface physics and may inspire new classes of photonic devices that exploit collective modes for enhanced functionality.
This paper also resonates with ongoing efforts to push metasurfaces from laboratory curiosities into commercially viable technologies. The scalable fabrication of the metasurface, compatible with on-chip integration and possibly CMOS processes, suggests a feasible path toward widespread adoption. This aspect is critical to scaling the technology for industrial applications.
The color router’s design flexibility further opens possibilities for dynamic tuning or reconfiguration when combined with active materials or phase-change components. Such developments could lead to adaptive optics and smart photonic systems capable of responding to changing environmental inputs or user demands, all while maintaining high routing efficiencies.
In summary, this discovery not only provides a powerful solution to a vexing problem in photonic engineering but also reshapes the conceptual framework within which metasurfaces can be designed. By conquering the efficiency loss previously deemed unavoidable in spatial multiplexing, the researchers chart a path toward nanoparticles capable of extraordinary multifunctionality, compactness, and performance.
Looking forward, this breakthrough invites a reevaluation of how multifunctionality should be approached in metasurface engineering, encouraging the exploration of collective phenomena instead of segmented design paradigms. The ripple effects of this research might well accelerate the convergence of photonics with information technologies, leading to faster, smaller, and more efficient optical devices that were previously deemed impractical.
Ultimately, this first-of-its-kind on-chip nonlocal metasurface for color routing stands as a beacon for future exploration, offering vast potential across telecommunication, display technology, augmented reality, and beyond. As the field advances, such innovations will be critical stepping stones toward realizing the full promise of metasurface-enabled photonics.
Article References:
Shi, Y., Wan, S., Wang, Z. et al. On-chip nonlocal metasurface for color router: conquering efficiency-loss from spatial-multiplexing. Light Sci Appl 15, 66 (2026). https://doi.org/10.1038/s41377-025-02146-9
Image Credits: AI Generated
DOI: 10.1038/s41377-025-02146-9 (Published 12 January 2026)
Tags: collective interactions in opticscolor routing efficiencyelectromagnetic wave manipulationinnovative metasurface technologyintegrated photonics advancementsnext-generation optical routingon-chip nonlocal metasurfacesoptical device performancephotonic device efficiencyspatial multiplexing in photonicsultra-thin planar structureswavelength separation techniques
