| Literature DB >> 28600570 |
Atsushi Ishikawa1,2,3, Shuhei Hara4, Takuo Tanaka5,6,7, Yasuhiko Hayashi4, Kenji Tsuruta4.
Abstract
Plasmonic metamaterials have overcome fundamental limitations in conventional optics by their capability to engineer material resonances and dispersions at will, holding great promise for senEntities:
Year: 2017 PMID: 28600570 PMCID: PMC5466669 DOI: 10.1038/s41598-017-03545-8
Source DB: PubMed Journal: Sci Rep ISSN: 2045-2322 Impact factor: 4.379
Figure 1Design and fabrication of metamaterials. (a) Schematic unit cell of a metamaterial on a Si substrate consisting of an Au nano-rod pair with a horizontal coupling antenna to break the structural symmetry. The surface structure was designed to exhibit the pronounced Fano resonance at 1730 cm−1, which spectrally overlapped with the C=O vibrational mode. (b–d) SEM images of the fabricated metamaterials with different antenna lengths of h/s = 0.75 (red), 0.52 (blue), and 0.33 (green) to tune the excitation of the Fano resonance. To match the Fano-resonant frequencies of all the metamaterials even with different antenna lengths, other geometry parameters were carefully designed (see the Methods section).
Figure 2Near-field responses of a metamaterial-molecular coupled system. (a) Schematic of the mode interaction. The interference between the dipole (ω D) and quadrupole (ω Q) plasmon modes produces the Fano resonance, which resonantly coupled with the C=O vibrational mode (ω C=O). Numerically simulated |E|2 spectral responses at the gap center of the metamaterials (b) without and (c) with the C=O mode. (d) Corresponding |E| distributions at ω D and ω Q in (b) and at ω C=O in (c) for h/s = 0.75 (red). At the Fano resonance (ω Q), the y-polarized incident electric field is highly localized within the gap, inducing strong gap plasmon to re-radiate the x-polarized light. The C=O mode strongly quenches the Fano resonance by disturbing the sensitive mode interference, translating into distinct far-field spectral response.
Figure 3IR characterization of metamaterials. (a) Experimental setups of FT-IR transmission measurement for the co- and cross-polarizations. Experimentally measured transmission spectra of the metamaterials for the (b) co- and (c) cross-polarizations. (d, e) Corresponding numerical simulations, which well reproduced the experimental results qualitatively and quantitatively. The excitation of the Fano resonance in the shaded region is manifested as a transmission dip for the co-polarization, but as a transmission peak for the cross-polarization. The spectra in (c) and (e) have been multiplied by 10 for clarify.
Figure 4Polarized metamaterial-enhanced IR absorption. Experimentally measured transmission spectra of a 50-nm thick PMMA film on the metamaterials for the (a) co- and (b) cross-polarizations. (c,d) Corresponding numerical simulations, which well reproduced the experimental results qualitatively and quantitatively. The resonant coupling of the Fano and C=O modes at ω C=O, indicated by the dashed lines, results in an anti-resonant peak (dip) for the co- (cross-) polarization within the Fano-line shapes of the metamaterials. The cross-polarized detection scheme selectively extracts the light interacting with the metamaterial-molecular coupled system, thus dramatically improving the vibrational signal contrast compared to the conventional co-polarized case. The spectra in (b) and (d) have been multiplied by 10 for clarify.
Figure 5Comparison of the measured signal strengths between the co- and cross-polarizations. (a) Co- and (b) cross-polarized transmission spectra of a PMMA thin film on the metamaterials by progressively decreasing the solid content of PMMA solution. (c) Extracted signal strengths as the function of the PMMA concentration, and (d) the same ones as the function of the number of PMMA molecules within the unit cell.