Abstract
Beam combiners are widely used in various optical applications including optical communication and smart detection, which spatially overlap multiple input beams and integrate a output beam with higher intensity, multiple wavelengths, coherent phase, etc. Since conventional beam combiners consist of various optical components with different working principles depending on the properties of incident light, they are usually bulky and have certain restrictions on the incident light. In recent years, metasurfaces have received much attention and become a rapidly developing research field. Their novel mechanisms and flexible structural design provide a promising way to realize miniaturized and integrated components in optical systems. In this paper, we start from studying the ability of metasurfaces to manipulate the incident wavefront, and then propose a metasurface beam combiner in theory that generates an extraordinary refracted beam based on the principle of phase gradient metasurface. This metasurface combines two monochromatic light incidents at different angles with identical polarization but arbitrary amplitudes and initial phases. The combining efficiency, which is defined as the ratio of the power in the combining direction to the total incident power, is 42.4% at the working wavelength of 980 nm. The simulated results indicate that this proposed method is able to simplify the design of optical combiners, making them miniaturized and integrated for smart optical systems.
Highlights
Classic beam combining technologies, including polarization beam combining, wavelength beam combining and coherent beam combining, enable an amplification of the power of output light while ensuring good beam quality [1,2,3,4,5]
In order to design the beam combiner with an unchanged polarization state, we decided to focus on the gradient metasurface
Compared with conventional coherent beam combining technology, our metasurface beam combiner has no restriction on the phase and amplitude of the incident beams, and the unchanged polarization and wavelength make sure the output light could continue to be combined any number of times
Summary
Classic beam combining technologies, including polarization beam combining, wavelength beam combining and coherent beam combining, enable an amplification of the power of output light while ensuring good beam quality [1,2,3,4,5]. The first two beam combining technologies are classified as incoherent beam combining technologies, and their basic components are a polarizing beam splitter (BS) and dichroic BS, respectively Both incoherent beam combiners can achieve 100% combining efficiency in theory, because they combine light of different incoherent properties, and the combining efficiency is only limited by the transmittance. The conventional coherent beam combiner proportionally combines the reflected light and the transmitted light illuminated from different sides of the lens at 45◦ , respectively. This mechanism makes the combination of coherent light inevitably lossy. The incident light must have fixed directions and angles, making conventional coherent beam combiners difficult to integrate into a compact optical system
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
