Fig. 1. Ultra-broadband plasmonic metamaterial absorber. (a) 3D schematic of the absorber. (b) Front view of the unit cell of the absorber. (c) Typical metamaterial absorber with sandwiched MDM configuration and obtained absorption spectra. The geometric parameters are consistent with model 1. The period of the structure is 220 nm, thickness of the substrate is 300 nm, radius of metal and dielectric is 100 nm, and heights of metal and dielectric are 45 and 25 nm, respectively.

Fig. 2. Absorption spectra of the proposed absorbers. (a)–(d) Obtained absorption spectra with (red dashed line) or without (dark green solid line) covering a layer of Al2O3 of models 1 to 4. The grey dashed line indicates the standard spectrum of solar radiance AM 1.5.

Fig. 3. Absorption under different incident conditions. (a) Contour plot of the absorption spectra for TE mode and (b) TM mode at different incident angles from 0° to 70° with a step of 5°. (c) Absorbance spectra with different incident angles for TE mode and (d) TM mode. (e) Average absorption from 0.2 to 7 μm as a function of incident angle with TE and TM modes.

Fig. 4. Electric field (|E|) distributions (surface plot) and Poynting vectors (white arrows) in a unit cell at different wavelengths, where TM-polarized light with normal incidence is chosen. The upper figures represent the short-wavelength region; lowers are the long-wavelength region. The position of the monitor is located at y=0  nm. The red dashed frame indicates where the light is confined in the absorber.

Fig. 5. Absorber structure can be considered as a set of G-SPP resonators. (a) Schematic of light propagation in the cross section of the absorber and the resulting resonance mode. (b) G-SPP mode effective index with various dielectric film thicknesses and (c) its propagation lengths as a function of incident wavelengths. (d) Equivalent structure diagram of the absorber section. (e) Required height to maintain FP resonance versus resonance wavelength for different phase shifts. The red dashed line shows the corresponding height in the absorber. (f) Phase shift of the G-SPP in cavity 2. The monitor is placed in the center of the cavity.

Fig. 6. Absorption spectra with different structure parameters. (a) Period p. (b) Radius of dielectric nanowires r1. (c) Radius of dielectric nanorings r2. (d) Distance between the bottom nanoring and metallic film h1. (e) Height of the nanorings h2. (f) Number of nanorings coated on a nanowire n.

Fig. 7. Average absorption with different structure parameters. (a) Period p. (b) Radius of dielectric nanowires r1. (c) Radius of dielectric nanorings r2. (d) Distance between the bottom nanoring and metallic film h1. (e) Height of the nanorings h2. (f) Number of nanorings coated on a nanowire n.

Fig. 8. Magnetic field (|H|) distributions and Pabs (in log scale) in a unit cell at typical wavelengths, where TM-polarized light with normal incidence is chosen. The position of the monitor is located at y=0  nm.

Fig. 9. Absorption spectra with different structure parameters. (a) Distance between two nanorings h3. (b) Remaining height of dielectric nanowires h4. (c) Refractive index of the dielectric RI.

Fig. 10. Average absorption with different structure parameters. (a) Distance between two nanorings h3. (b) Remaining height of dielectric nanowires h4. (c) Refractive index of the dielectric RI.