In a groundbreaking advancement poised to redefine the field of holography and photonics, researchers have developed innovative longitudinally engineered metasurfaces capable of generating intricate 3D vectorial holograms. This pioneering work addresses critical limitations faced by conventional holographic technologies, offering unprecedented control over the complex three-dimensional vectorial fields of light. The technique harnesses metasurfaces—ultrathin, nano-engineered interfaces—and strategically engineers them along the propagation axis to modulate light’s amplitude, phase, and polarization with exquisite precision. The results promise transformative applications ranging from advanced display systems and optical communications to quantum information processing and holographic microscopy.
Historically, traditional metasurface designs have primarily focused on manipulating light properties transversely, effectively creating two-dimensional holographic images. However, extending control into the third dimension—mapping not only spatial positioning but the vectorial nature of optical fields throughout a volume—demands a novel approach. The study introduces a new class of metasurfaces that are longitudinally structured, meaning their geometrical and electromagnetic parameters vary along the direction of light travel. This contrasts with usual metasurfaces, which are essentially planar. Such longitudinal engineering facilitates the encoding of volumetric vector information, enabling projection of dynamic, complex 3D holograms with vectorial polarization patterns.
Technically, these metasurfaces consist of multilayered nano-resonators constructed from carefully selected dielectric materials with high refractive indices and low optical losses. By stacking these functional layers with subwavelength spacing and tuning their shapes and orientations, the team created a metasurface architecture that offers independent and simultaneous control over phase, amplitude, and polarization at different depths within the hologram volume. This longitudinal modulation is crucial for achieving full vectorial holography, where the vector components of the electromagnetic field (including the three-dimensional state of polarization) can be sculpted arbitrarily in space.
The underpinning physics relies on controlling the resonant effective medium responses within each layer, enabling a tailored response to incident light waves. These layered resonators introduce phase delays and polarization rotations that, when combined, synthesize highly complex optical wavefronts. Such precision demands rigorous computational design tools, including inverse electromagnetic scattering algorithms and deep learning optimization, to determine layer geometries that yield desired three-dimensional vectorial field distributions. This computational approach represents a significant leap from standard forward design methodologies prevalent in metasurface engineering.
One of the standout features demonstrated by the researchers is the ability to produce vectorial holograms that encode 3D images with arbitrarily varying polarization and intensity distributions throughout the holographic reconstruction volume. Unlike scalar holograms, which only recreate amplitude or phase profiles, vectorial holograms generate light fields with specific polarization states dynamically evolving in space. This capability opens new frontiers for holographic displays capable of rendering photorealistic, polarization-encoded information, crucial for realistic visualization, augmented reality (AR), and data-rich optical security systems.
Experimentally, the team validated their approach by fabricating multilayer metasurface samples using state-of-the-art nanofabrication techniques including electron beam lithography and atomic layer deposition to realize precise dielectric nano-structures. These samples were illuminated with coherent laser sources at visible and near-infrared wavelengths. Comprehensive optical characterization using polarization-resolved microscopy and interferometric imaging confirmed the 3D vectorial holographic reconstructions closely matched the predetermined target fields. Such validation signals a major milestone for translating computational designs into practical, scalable devices.
Beyond aesthetic visualization, vectorial holography offers revolutionary enhancements in optical communication. Encoding information into the vectorial states of light across three-dimensional volumes significantly boosts data capacity. The longitudinal metasurface approach allows spatial multiplexing of vector polarization channels along the propagation axis, supplementing traditional multiplexing schemes in frequency and time domains. This capability could lead to next-generation optical fibers and free-space communication systems with dramatically increased throughput and robustness to eavesdropping.
In the realm of quantum technologies, the precision control of polarization vector fields in 3D also bears immense promise. Polarization states can serve as quantum bits or qudits, the fundamental carriers of quantum information. By engineering metasurfaces that impose tailored vectorial transformations on photons, the researchers lay groundwork for intricate quantum state manipulations and high-dimensional quantum entanglement distributions. This foundational platform could be leveraged in quantum networks, secure quantum communications, and advanced sensing.
Moreover, biomedical imaging and microscopy stand to gain substantially. Vectorial holography facilitates unprecedented control of light-matter interactions, enabling the tailoring of focus, phase, and polarization at nanoscale spatial resolutions within biological specimens. The longitudinally engineered metasurfaces can produce tightly confined beams with spatially variant polarization states matched to specific imaging modalities, improving contrast and enabling novel functional imaging techniques that extract molecular orientation and composition from complex tissues.
The theoretical frameworks developed in this study also extend fundamental understanding of light scattering and wavefront shaping in structured media. The researchers framed their metasurface design in terms of longitudinal effective medium theories and multipole expansions, allowing analytic insight into how layered nanostructures modulate vectorial fields progressively along propagation direction. This enriched conceptual model can accelerate new breakthroughs in photonics design beyond holography, such as complex polarization converters and vectorial vortex beam generators.
From a materials standpoint, the choice of dielectric materials exhibiting low losses at visible and infrared wavelengths represents an essential enabling factor. Metallic metasurfaces, though popular, suffer from absorption losses that degrade optical efficiency and limit phase control. By selecting first-principles engineered low-loss dielectrics and employing high-precision nanofabrication methods, the team achieved both high-efficiency optical modulation and robust vectorial control. This approach sets a new standard for practical metasurface device fabrication.
As 3D vectorial holography continues to mature, challenges remain in scaling fabrication to larger areas and improving dynamic reconfigurability. Current devices are static, based on fixed nanostructure geometries, but future iterations incorporating phase-change materials or micro-electromechanical systems (MEMS) could enable active modulation of vectorial holograms on demand. Such developments would unlock real-time holographic displays with full depth and vectorial control, revolutionizing AR/VR interfaces and interactive optical communication terminals.
In summary, the longitudinal metasurface engineering approach unveiled in this work constitutes a paradigm shift in holography, demonstrating the first practical pathway toward volumetric 3D vectorial holograms with full polarization control. The implications ripple across scientific disciplines, promising innovations in visualization, telecommunications, quantum technologies, and biomedical optics. As fabrication and computational design techniques continue to advance synergistically, the prospect of fully immersive, dynamically controllable vectorial holography is rapidly becoming a tangible reality.
This pioneering research not only expands the boundaries of what metasurfaces can achieve but also sets a visionary roadmap for next-generation photonic technologies. Holograms that were once the stuff of science fiction will soon be engineered with nanometric precision, delivering multidimensional information encoded in light’s fundamental vectorial nature. The horizon for optical science and engineering is brighter and more intricately detailed than ever before.
Subject of Research:
Longitudinally engineered metasurfaces designed for generating 3D vectorial holograms with precise control over amplitude, phase, and polarization in volumetric optical fields.
Article Title:
Longitudinally engineered metasurfaces for 3D vectorial holography.
Article References:
Tan, L., Huo, P., Lin, P. et al. Longitudinally engineered metasurfaces for 3D vectorial holography. Light Sci Appl 15, 36 (2026). https://doi.org/10.1038/s41377-025-02158-5
Image Credits:
AI Generated
DOI:
03 January 2026
Tags: 3D vectorial holographyadvanced display systemsadvanced holographic technologiesdynamic hologram projectionholographic microscopy applicationslongitudinal metasurfacesnano-engineered interfacesoptical field manipulationphotonics innovationsquantum information processingultrathin metasurfacesvolumetric vector information
