Metasurfaces enhance optical systems | Laser Focus World
The exploration of meta-optics marks a pivotal chapter in the evolution of optical technologies and presents a paradigm shift in how light is manipulated at the microscopic level. This remarkable journey from conceptual frameworks to tangible applications epitomizes the confluence of physics, materials science, and engineering, and heralds a new era of compact and efficient optical systems.
At the heart of this technological revolution are metamaterials—synthetically engineered materials endowed with unique properties unattainable in natural substances. These materials paved the way for the development of metasurfaces, two-dimensional (2D) counterparts that manipulate light at the subwavelength scale to offer unprecedented control over electromagnetic waves. This manipulation is achieved through the design of metalenses—flat lenses crafted from optical components based on metasurfaces that direct and focus light with high precision.
Metasurfaces
Metasurfaces can be active or passive. Passive metasurfaces offer fixed functionalities—serving as static elements in optical systems. In contrast, active metasurfaces represent a leap forward to tunable, reconfigurable, and time-varying functionalities. This critical innovation enables embedding multiple functions into a single layer for precise control over light’s polarization and trajectory. Consequently, bulky optical systems can now be reimagined into exceedingly small form factors, which opens the door to novel properties and applications previously deemed inaccessible with existing optical hardware.
Despite the promising capabilities of metamaterials and metasurfaces, the technology works predominantly within a narrow rather than broadband spectral operation range. Although strides are being made toward achieving broadband capabilities, challenges in efficiency, performance, and mass production persist. Nevertheless, narrowband applications are robust and driving innovation in sectors such as light detection and ranging (LiDAR) for autonomous vehicles, three-dimensional (3D) sensing, and general biometrics.
The global market for metamaterials is on an impressive growth trajectory, which is fueled by increasing applications in telecommunications, imaging, and sensing technologies. The metamaterial market size was valued at approximately $500 million in 2021 and is projected to reach over $3 billion by 2026—growing at a compound annual growth rate (CAGR) of 36%.1 This growth is attributed to metamaterials applications expanding into industries such as automotive, aerospace and defense, consumer electronics, and healthcare. Major industry players are already exploring these possibilities.
An optical revolution is underway
Materials engineering provider Applied Materials is redefining optical components. By creating etched waveguides and flat near-infrared (NIR) lenses on a 300 mm transparent substrate, the company showcases metamaterials in optical engineering. These components, characterized by thinness, multifunctionality, and compatibility with semiconductor nanofabrication processes, underscore significant advancements within the field. The ability to control optical elements at the nanoscale, with precise uniformity across wafers, represents a monumental leap in optical manufacturing.
Samsung Advanced Institute of Technology is at the forefront of harnessing metasurfaces for cutting-edge applications such as LiDAR—a technology crucial for autonomous driving, augmented and virtual reality, and gesture sensing. LiDAR systems, which measure distances by illuminating targets with laser light and analyzing the reflected light, are evolving. The shift toward small solid-state systems illustrates the industry’s trend toward more robust, shock-resistant solutions. Samsung’s development of a novel solid-state LiDAR system, which leverages an active metasurface based on indium tin oxide (ITO), offers enhanced scanning approaches and higher resolution at greater distances.
Metalenz, a spinoff from Harvard University, embodies the successful bridge from academic research to commercial viability. The company has harnessed deep-ultraviolet (DUV) lithography in semiconductor foundries to mass-produce metasurfaces with high optical yields. By collaborating with companies like ST Microelectronics and UMC, Metalenz introduced a dot pattern projector and the award-winning polarization imaging system (see Fig. 1). These innovations not only enhance 3D sensing in smartphones and IoT devices, but also introduce groundbreaking applications in biometric authentication and machine vision, which marks a significant leap toward compact, multifunctional optical solutions.
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