Negative permeability around 630 nm in nanofabricated vertical meander metamaterials

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • Heinz Schweizer - , University of Stuttgart (Author)
  • Liwei Fu - , University of Stuttgart (Author)
  • Hedwig Gräbeldinger - , University of Stuttgart (Author)
  • Hongcang Guo - , University of Stuttgart (Author)
  • Na Liu - , University of Stuttgart (Author)
  • Stefan Kaiser - , University of Stuttgart (Author)
  • Harald Giessen - , University of Stuttgart (Author)

Abstract

We demonstrate a new design of a 3-dimensional meander structure that exhibits negative permeability with a broad bandwidth between 550 nm and 665 nm. The structural design allows for full coupling of the magnetic field component at all angles of incidence. We compare our structure with other metamaterial structures with respect to the series capacitance contributions of the different metamaterials. The investigation of optical metamaterials is carried out combining transmission line analysis with numerical simulations of Maxwell's equations. The analysis is demonstrated for typical split ring structures and the novel 3D meander metamaterial structures. Comparing the resulting scattering parameter spectra as well as the retrieved effective material parameters, we find that transmission line description remains valid for metamaterials at optical frequencies. We find in addition that the longitudinal capacitance is the decisive parameter to achieve negative permeability with a broad bandwidth at optical frequencies. For experimental verification we manufactured split-ring resonator structures and meander metamaterial structures with linewidths down to 30 nm, element sizes down to 100 nm, and periods between 200 nm and 350 nm. For meander metamaterial structures a permeability value of -1 was achieved within a bandwidth of 50 nm centered at 630 nm. The largest absolute value of -4.5 was achieved at 650 nm.

Details

Original languageEnglish
Pages (from-to)3886-3900
Number of pages15
JournalPhysica Status Solidi (A) Applications and Materials Science
Volume204
Issue number11
Publication statusPublished - Nov 2007
Peer-reviewedYes
Externally publishedYes

External IDs

ORCID /0000-0001-9862-2788/work/142255411