Advanced Materials Interfaces (Jul 2024)

Thermally Stable 3D‐Metamaterial Designs with Advanced Hyperbolic Dispersion Manipulation and Magnetic Anisotropy

  • Jiawei Song,
  • Di Zhang,
  • Matteo Moceri,
  • Hongyi Dou,
  • Xinghang Zhang,
  • Haiyan Wang

DOI
https://doi.org/10.1002/admi.202400132
Journal volume & issue
Vol. 11, no. 21
pp. n/a – n/a

Abstract

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Abstract Hybrid metamaterials (HMs) have attracted significant research interests owing to their unique optical properties and their ability to manipulate light‐matter interaction in a novel and controlled fashion beyond what any single material offers. Especially 3D HMs are of great interest due to their potential to provide advanced and precise control of such light‐matter interaction in nanoscale. In this study, a set of 3D HM nanocomposite films are designed by integrating three phases, i.e., vertically aligned CoFe2 nanosheets within the matrix of TiN/TaN multilayers. By increasing the number of TiN/TaN multilayers from 2 to 19, a high degree of tunability in optical property has been demonstrated, including well‐tailored optical permittivity, and tunable hyperbolic dispersion from Type‐II to Type‐I. Ferromagnetic CoFe2 nanosheets introduces novel magnetic responses, such as magnetic anisotropy and enhanced coercivity. Furthermore, in situ heating X‐ray diffraction (XRD) suggests good thermal stability of the 3D nanocomposite films up to the measured temperature of 600 °C. This three‐phase 3D nanocomposite design offers more flexibility in HM designs, multifunctionalities, and phase stability, compared with the typical two‐phase HMs toward future metamaterials by design.

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