In the annals of technological history, the pixel has long been recognized as the fundamental unit of digital imagery. Coined initially as “picture element” in 1927 within the pages of the American magazine Wireless World, the pixel has evolved into an omnipresent component of modern technology. It forms the backbone of computer displays, television screens, and digital cameras, facilitating the creation and capture of vibrant images. Traditionally, pixels have held a singular role in either modulating light to display images or detecting light to capture them. However, a groundbreaking breakthrough from ETH Zurich challenges this dichotomy by introducing a pixel capable of performing both functions simultaneously, heralding a new era for imaging and display technologies.
A pioneering research team helmed by Professor David Norris at the Optical Materials Engineering Laboratory at ETH Zurich has devised a new class of pixels known as Fourier pixels. These sophisticated pixels transcend conventional boundaries by not only steering light but also analyzing it within a single device. Unlike traditional pixels that focus merely on light intensity, Fourier pixels manipulate and decipher intricate properties of light waves, including oscillation phase and polarization. This multifaceted control opens unprecedented possibilities, envisioning next-generation camera-display hybrids that seamlessly integrate image capture and projection in compact formats.
The cornerstone of these innovations lies in exploiting the wave phenomenon of light, particularly its interference. When light waves scatter off a surface, they overlap, producing complex interference patterns determined by the relative oscillation phases of the waves. Surfaces shaped at a nanometric scale can tailor these phase relations to induce constructive or destructive interference, effectively modulating the emergent light landscape. Professor Norris and his colleagues have skillfully employed this principle, fabricating sculpted surfaces with nanometer precision, enabling meticulous control over the behavior of scattered light through tailored wavefront engineering.
The operational mechanics of the Fourier pixel involve an intricate interplay between incident light and engineered surface waves known as surface plasmon polaritons. upon striking the pixel, incoming light is transformed into these quasi-particles propagating along the material’s surface. Subsequently, at a distinct locale within the pixel’s domain, the surface waves are re-emitted into free-space light waves. The resultant light waves interfere, producing controllable patterns that translate into images. The team leverages mathematical Fourier analysis to reverse-engineer the precise surface topographies required to generate desired image projections, merging physics with computational design for unparalleled optical finesse.
Beyond merely orchestrating light intensity, these advanced pixels wield command over light’s polarization—a vector describing the orientation of its electric field oscillations. By synthesizing and overlapping surface waves with varying polarization states, the researchers can shape the polarization direction of the re-emitted light. This capability introduces a new parameter for visual information encoding and decoding within single pixels, previously unattainable in standard display or sensor technologies. The ability to modulate polarization at such granular levels offers promising avenues for enhanced optical communication, imaging contrast, and novel photonic devices.
Equally remarkable is the Fourier pixels’ capacity to finesse the oscillation phase of light. This manipulative power allows the crafting of exotic light configurations, such as doughnut-shaped beams characterized by a central intensity null. Such beam shapes find utility across fields from optical tweezers to high-resolution microscopy and quantum information processing. Importantly, these effects are achievable across multiple wavelengths, paving the way for full-color image generation and manipulation through unified pixel architectures, thereby integrating spectral versatility with comprehensive light control.
Reversing the directional flow of information, Fourier pixels also function as analyzers of incident light waves. By overlaying an incoming wave with a reference beam on the pixel surface, interference patterns emerge that encode the phase information of the light in question. Captured via a camera and processed through computational algorithms, these patterns reveal the phase structure of the light source. A similar methodological framework applies to decode polarization states, enabling a single pixel to extract multifaceted optical information. This bidirectional modality creates a paradigm shift in how light interactions may be harnessed in devices.
The synthesis of control and analysis within the singular Fourier pixel is achieved through an elegant application of Fourier analysis, a mathematical technique that decomposes complex functions into fundamental wave components. This approach simplifies the design and fabrication of surface profiles necessary for combined amplitude, phase, and polarization manipulation without resorting to prohibitively complex computational models. The result is a versatile pixel construct that bridges wave physics and nanofabrication, offering scalable potential for integration into advanced optical systems.
Given light’s ubiquitous role in technologies spanning from consumer electronics to high-speed internet fiber optics, the introduction of such bidirectional pixels portends significant technological impacts. Professor Norris envisions these pixels becoming instrumental in fields as diverse as compact imaging systems, adaptive displays, and optical computing. The ability to perform mathematical computations intrinsically within the pixel material itself, bypassing the need for external electronic computation, may accelerate the development of highly responsive photonic devices that dynamically adapt to visual input in real time.
Near-term objectives for this line of research include scaling up the individual Fourier pixel into interconnected matrices comprising millions of pixels, akin to the microarchitecture of modern cameras and screens. Such pixel arrays would enable complex image capture, processing, and projection functionalities in unified platforms. This leap from single-pixel demonstrations to full-scale device matrices will be critical to translating the exceptional control capabilities into consumer-ready, commercial technologies.
In recognition of its transformative potential, the technology underpinning Fourier pixels has been patented and nominated for ETH Zurich’s prestigious Spark Award, spotlighting innovations with high societal and commercial relevance. This acknowledgment underscores the promise of these bidirectional pixels to redefine optical devices and possibly institute a new standard in how images are generated, sensed, and manipulated at the fundamental unit of pixels.
As the field of photonics advances, innovations such as Fourier pixels illustrate the profound interplay between foundational physics, advanced mathematical frameworks, and state-of-the-art nanofabrication. This convergence is unlocking fresh dimensions in light manipulation, offering both scientific intrigue and practical utility. The future conceived by Professor Norris and his team imagines a world where digital imagery and sensing coalesce in seamless harmony, fundamentally reshaping how we interact with visual information.
Subject of Research: Bidirectional pixels enabling simultaneous light control and analysis through Fourier optics and nanofabricated surface plasmon polariton systems.
Article Title: Fourier pixels for bidirectional light control
News Publication Date: 24-Jun-2026
Web References:
– https://www.nature.com/articles/s41586-026-10681-7
– http://dx.doi.org/10.1038/s41586-026-10681-7
References:
– Norris, D., Glauser, Y., Vonk, S., et al. (2026). Fourier pixels for bidirectional light control. Nature. DOI: 10.1038/s41586-026-10681-7
Image Credits: ETH Zurich Optical Materials Engineering Laboratory
Keywords: Bidirectional pixel, Fourier optics, surface plasmon polaritons, light interference, phase control, polarization manipulation, nanofabrication, computational imaging, photonics, optical sensors, display technology, light wave analysis
