A new publication from Opto-Electronic Advances; DOI 10.29026/oea.2024.230216 , discusses liquid crystal-integrated metasurfaces for an active photonic platform.
In the field of optical science, the exploration of metasurfaces has garnered significant attention over the last few decades. Metasurfaces represent a sophisticated evolution of traditional optical components, comprising nanostructures meticulously arranged to enable precise control over light manipulation. These nanostructures function as building blocks, allowing for the creation of lenses with unique properties, such as extreme thinness, lightweight design, and miniaturization. The intrinsic appeal of metasurfaces lies in their potential to supersede existing optical systems while introducing novel functionalities unattainable through conventional means. Their capabilities extend beyond mere replacement, offering features like expanded field-of-view and enhanced resolution. This versatility has ignited interest in applications spanning diverse domains, including displays, sensors, augmented/virtual reality (AR/VR), and light detection and ranging (LiDAR).
However, conventional metasurfaces face a fundamental limitation – their static nature impedes dynamic responses, akin to stationary structures devoid of adaptability. Addressing this limitation has led to the conceptualization of an "active photonic platform," aiming to impart metasurfaces with dynamic responsiveness. The realization of an active photonic platform involves strategic collaboration with materials capable of dynamic property alterations. This paper delves into a crucial collaborator in this pursuit – liquid crystals. Liquid crystals possess advantages such as the rapid modulation of optical properties within milliseconds across a broad spectrum, including visible, IR, and THz bands. Their notable transparency in the visible range makes them exceptionally well-suited for practical applications. Moreover, as evident from their use in liquid crystal displays, the mass production capability and industrial feasibility of liquid crystals have already been validated, positioning them as the most promising candidate for an active metasurface.
The authors of this article investigated the synergistic integration of liquid crystals with metasurfaces. The exploration commenced with a meticulous analysis of the advantages and disadvantages of liquid crystals, including a comparative examination of different types such as nematic, smectic, columnar, and cholesteric liquid crystals. Subsequently, the study delved into recent advancements, elucidating how liquid crystals, when integrated with metasurfaces, contribute to functionalities such as hologram, lens, beam steering, transmissive/reflective modulation, and absorber. The exploration extended to potential applications in cutting-edge technologies like AR/VR, encryption, and sensors. Furthermore, this article delves into the challenges and future directions of integrating liquid crystals with metasurfaces, providing detailed examples and explanations. Despite significant efforts to create practical photonic platforms, limitations persist, necessitating joint research on liquid crystals and metasurfaces. This review serves as a guide, offering insights into their collaborative potential and aiding in the identification of research trends for tunable metasurfaces.
This paper serves as a comprehensive exploration of the collaborative integration of liquid crystals with metasurfaces, shedding light on the scientific intricacies that underpin this advanced optical technology. Beyond the analysis of advantages, disadvantages, and recent studies, it is crucial to consider the methodological approaches and emerging trends to facilitate a holistic comprehension of the subject matter. The integration of liquid crystals with metasurfaces presents a promising avenue for the development of dynamic optical systems, paving the way for transformative applications in various technological domains.
Keywords: tunable metasurface / liquid crystal / active metasurface / electrically tunable optical system
