Abstract
AbstractOptical metasurfaces are judicously engineered electromagnetic interfaces that can control and manipulate many of light’s quintessential properties, such as amplitude, phase, and polarization. These artificial surfaces are composed of subwavelength arrays of optical antennas that experience resonant light-matter interaction with incoming electromagnetic radiation. Their ability to arbitrarily engineer optical interactions has generated considerable excitement and interest in recent years and is a promising methodology for miniaturizing optical components for applications in optical communication systems, imaging, sensing, and optical manipulation. However, development of optical metasurfaces requires progress and solutions to inherent challenges, namely large losses often associated with the resonant structures; large-scale, complementary metal-oxide-semiconductor-compatible nanofabrication techniques; and incorporation of active control elements. Furthermore, practical metasurface devices require robust operation in high-temperature environments, caustic chemicals, and intense electromagnetic fields. Although these challenges are substantial, optical metasurfaces remain in their infancy, and novel material platforms that offer resilient, low-loss, and tunable metasurface designs are driving new and promising routes for overcoming these hurdles. In this review, we discuss the different material platforms in the literature for various applications of metasurfaces, including refractory plasmonic materials, epitaxial noble metal, silicon, graphene, phase change materials, and metal oxides. We identify the key advantages of each material platform and review the breakthrough devices that were made possible with each material. Finally, we provide an outlook for emerging metasurface devices and the new material platforms that are enabling such devices.
Highlights
Harnessing, controlling, and understanding light have been long-standing pursuits of human civilization, dating back to ancient times
We identify the key advantages of each material platform and review the breakthrough devices that were made possible with each material
After years of exploration and discovery, we find ourselves surrounded with optical technologies that have advanced our ability to detect early signs of disease, transmit data across the world at the speed of light, and stream high-definition movies on our phones during class lectures
Summary
Harnessing, controlling, and understanding light have been long-standing pursuits of human civilization, dating back to ancient times. With current trends to progressively miniaturize technology, it is essential to look for alternative methods to control light at extremely small dimensions This miniaturization requires compact and planar devices with novel functionalities that can be realized via novel approaches that utilize artificial composite optical materials. Realize effective negative refractive index [1] and thereby can be utilized to make new devices such as lenses that can image beyond the diffraction limit [2] or invisibility cloaks [3] Practical realization of such MMs is limited due to numerous challenges such as harsh microfabrication and nanofabrication requirement for layered structures and significant optical losses in the materials.
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