Extreme "Meta" Optical Fiber Enabled by Gate tunable Metasurfaces and Zero index Materials

Abstract

Optical fiber is a well known example of a way to guide and manipulate light. It has been used extensively in various applications including long distance optical communication, light generation using fiber lasers, remote and optical sensing, fiber imaging in endoscopes, and fiber laser surgery. Although a dielectric optical waveguide is very efficient for transmitting light, its functionality is somewhat limited by the dielectric material of the core, which has poor electronic, magneto optical, and nonlinear optical responses and has the dielectric diffraction limit. Therefore, the optical properties of the optical fiber waveguide such as phase, amplitude, polarization state, and mode profile cannot be modulated after the fiber drawing fabrication, thus limiting the development of novel in fiber optical devices. The long range goal of the proposed research project is to develop effective methods for designing advanced optical applications using novel zero index materials and metasurfaces based optical fiber applications. The objective in this research project is to develop efficient tunable “meta” optical fibers with reconfigurable functionality such as phase modulation, enhanced magneto optical properties and light emission-lasing effects by merging the advantages of three distinct sciences, i) tunable transparent conducting oxide-metallic nitride epsilon near zero (ENZ) materials, ii) optical metasurfaces, and iii) nano-micro structured optical fibers. To achieve this objective, the PI will identify approaches which yield efficient control of the voltage tuned ENZ resonance in metasurface optical fiber phase and amplitude modulation. The PI will also use advanced techniques such as atomic layer deposition and wet chemistry synthesis to fabricate conducting oxide nano shell-film into nano-micro structured optical fiber for efficient ENZ resonance excitation and enhanced magneto optical-quantum emission effects.

Document Details

Document Type

DoD Grant Award

Publication Date

Jan 14, 2022

Source ID

FA95501910274

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