In a remarkable leap forward for photonics and metasurface technology, researchers from Nanjing University, under the guidance of Professors Yijun Feng and Ke Chen, have unveiled a pioneering approach that masterfully addresses a long-standing challenge in wavefront control. Their latest work introduces a novel hybrid-phase cooperative dispersion-engineering strategy that integrates Aharonov–Anandan (AA) and Pancharatnam–Berry (PB) geometric phases within a single-layer metasurface, unlocking unprecedented independent control over dual-spin achromatic wavefronts. This transformative methodology propels achromatic metasurfaces beyond traditional single-spin limitations, enabling broadband and multifunctional applications that could redefine how light manipulation is achieved across diverse spectral regimes.
Traditionally, manipulating electromagnetic waves via metasurfaces has been mired by the spectral dispersion inherent to wave propagation. Dispersion causes wavelength-dependent shifts in wavefront characteristics, such as steering angles and focal points, culminating in chromatic aberrations that degrade device performance over broad bandwidths. While metasurfaces have enabled planar, ultra-thin optical devices by precisely engineering subwavelength ‘meta-atoms,’ most existing achromatic designs have either catered to a single spin channel or imposed identical dispersion responses on both spin states. Such constraints drastically limit the integration of multi-channel functionalities in compact photonic devices.
The breakthrough from Nanjing University strategically addresses this bottleneck by exploiting the unique roles of AA and PB phases. The AA geometric phase operates by spin unlocking, effectively detaching the propagation paths and dispersion characteristics of right-handed circularly polarized (RCP) and left-handed circularly polarized (LCP) light. Concurrently, the PB phase extends the achievable phase range through global rotation of meta-atoms, enabling full 2π phase coverage indispensable for complete wavefront shaping. This sophisticated decoupling allows independent tailoring of phase and group delay for each circular polarization state within a single-layer metasurface, marking one of the first demonstrations of truly spin-unlocked dual-channel achromatic wavefront control.
Central to the device architecture is the deliberate design of asymmetric current distributions within each meta-atom. This asymmetry induces distinct resonance pathways for RCP and LCP waves, allowing their phase and dispersion properties to be engineered independently. By fine-tuning the resonant strength, the researchers achieve independent control over group delay — a critical parameter influencing the timing and spectral response of light waves. Complementing this, the local geometric rotation manipulates the PB phase, setting the desired phase profile with minimal interference in group delay, hence maintaining the achromatic integrity of each spin channel.
The team validated their approach experimentally in the microwave frequency range between 8 and 12 GHz. Two primary device classes were demonstrated: achromatic beam deflectors and achromatic metalenses. The beam deflectors showcased stable, spin-separated steering angles across the bandwidth, with RCP and LCP channels deflecting light to discrete, pre-designed directions without significant chromatic aberration. This capacity for dual-spin beam steering introduces compelling potential for multiplexed communication and imaging systems where polarization channels can carry independent information streams.
Achromatic metalenses fabricated in the study further underscore the versatility of the method. These lenses assign distinct focal points to RCP and LCP waves while maintaining robust, diffraction-limited focusing across the entire operational frequency range. Such dual-focus functionality in a planar, compact form factor distinguishes these meta-devices as versatile components for multi-functional optics, opening pathways for advanced imaging techniques and polarization-encoded information processing.
Extending beyond microwaves, the research proposed scalable designs suitable for the terahertz regime (0.8–1.2 THz), demonstrating the generalized nature of the hybrid-phase cooperative dispersion engineering framework. This scalability hints at the enormous potential to transfer this paradigm to optical frequencies, including the visible spectrum, nurturing future developments in broadband, polarization-multiplexed imaging and compact meta-optical devices suitable for integration into photonic circuits and consumer technologies.
Moreover, this work elevates the conceptual framework of metasurface engineering by recognizing spin as an independent degree of freedom and enabling its dual-channel achromatic control within a minimalist, single-layer platform. This advancement dissolves restrictions that have traditionally limited multifunctional metasurfaces to single-spin operations or demanded complex multi-layer architectures, thus simplifying fabrication while enhancing device capabilities.
Looking forward, the authors envision coupling this hybrid-phase strategy with cutting-edge inverse design algorithms such as genetic algorithms and deep learning techniques to optimize meta-atom geometries and system-level performances systematically. These computational tools can navigate complex design spaces rapidly, enabling practical and scalable devices tailored for specific applications ranging from AR/VR displays to space-based optical systems.
In essence, the research by Feng, Chen, and their team negotiates a fundamental challenge in broadband wavefront control and metasurface engineering. By deftly orchestrating the interplay of two complementary geometric phases, they have birthed a flexible and robust design paradigm that sets new standards for multifunctional, broadband, and achromatic meta-optical devices. This innovation not only enriches the theoretical understanding of spin-photonics but also lays the groundwork for next-generation photonic hardware with enhanced performance, integration, and operational bandwidth.
Such progress is poised to ripple across scientific and technological domains, potentially impacting telecommunications, medical imaging, remote sensing, and beyond. The ability to independently control two circular polarization channels with high precision and broad achromaticity can unlock novel multiplexing schemes and novel imaging modalities that capitalize on the expanded degrees of optical freedom.
As this research continues to evolve, bridging from microwave through terahertz to visible spectral regimes, it promises to revolutionize how optical systems are designed, engineered, and deployed. Its elegant convergence of fundamental physics, materials science, and computational design exemplifies the forefront of meta-optics research, heralding a new era where compact, multifunctional, and resilient optical devices become an everyday reality.
Subject of Research: Not applicable
Article Title: Broadband spin-unlocked achromatic meta-devices empowered by hybrid-phase cooperative dispersion engineering
News Publication Date: 16-Dec-2025
Web References: http://dx.doi.org/10.1186/s43074-025-00217-z
Image Credits: Image by School of Electronic Science and Engineering, Nanjing University
Keywords: metasurfaces, achromatic wavefront control, hybrid-phase engineering, Aharonov–Anandan phase, Pancharatnam–Berry phase, spin multiplexing, broadband photonics, meta-atoms, microwave metasurfaces, terahertz devices, dual-spin control, polarization multiplexing
Tags: achromatic meta-opticsAharonov-Anandan geometric phasebroadband light manipulationcompact optical device integrationdual-spin wavefront controlhybrid-phase dispersion engineeringmetasurface technology advancementsmultifunctional photonic devicesovercoming chromatic aberrationsPancharatnam-Berry geometric phasespectral regime applicationswavefront control challenges
