High-permittivity ceramics enabled highly homogeneous zero-index metamaterials for high-directivity antennas and beyond

Zero-index metamaterials (ZIMs) can support uniform electromagnetic field distributions at any frequency, but their applications are hampered by the ZIM's homogenization level-only 3 unit cells per free-space wavelength, which is fundamentally limited by the low-permittivity inclusions (epsilon r approximate to 12) and background matrix (epsilon r approximate to 1). Here, by filling high-permittivity SrTiO3 ceramic (epsilon r approximate to 294) pillars in BaTiO3 (epsilon r approximate to 25) background matrix, we demonstrate a highly homogeneous microwave ZIM with an over threefold increase in the homogenization level. Leveraging such a ZIM, we achieve not only an antenna, approaching the fundamental limit in the directivity with outstanding scalability, but also a concave lens with a focal length of as short as 1 lambda 0. Our highly homogeneous ZIM has profound implications in ceramics, ZIM-based waveguides and cavities, free-space wavefront manipulation, and microwave quantum optics, and opens up enormous possibilities in wireless communications, remote sensing, global positioning satellites, etc.