Solid Immersion Maxwell's Fish-Eye Lens Without Drain

“…For example, when m = 23, we obtain the corresponding eigenwavelength of WGMs λ ≈ 0.99 by solving Eq. (11). At the same wavelength, we analytically calculate the electric field patterns |E z | 2 of the imaging utilizing Eqs.…”

“…[3] Later on, Pendry theoretically proposed perfect lens that can produce ideal diffraction-free images, which utilizes the negative refractive index materials to restore the evanescent waves. [4] Following the concept of perfect lens, the superlens has been realized in metamaterials, [5][6][7][8][9][10][11] metals, [12,13] surface plasmonons, [14] and hyperbolic metamaterials. [15,16] At the same time, the hyperlens [17][18][19][20][21] as far-field super-resolution lens was also designed by hyperbolic metamaterials which can convert the near-field evanescent waves to the far-filed propagating waves.…”

“…The analytical results of super-resolution imaging agree well with the numerical results. In addition, due to the impedance mismatching between SICSL and the air interface, the whispering gallery modes (WGMs) [11] are excited and affect the imaging quality. We clarify the relation between the resolution and exciting WGMs by solving the eigen equations of SICSL.…”

Improving resolution of superlens based on solid immersion mechanism

“…For example, when m = 23, we obtain the corresponding eigenwavelength of WGMs λ ≈ 0.99 by solving Eq. (11). At the same wavelength, we analytically calculate the electric field patterns |E z | 2 of the imaging utilizing Eqs.…”

“…[3] Later on, Pendry theoretically proposed perfect lens that can produce ideal diffraction-free images, which utilizes the negative refractive index materials to restore the evanescent waves. [4] Following the concept of perfect lens, the superlens has been realized in metamaterials, [5][6][7][8][9][10][11] metals, [12,13] surface plasmonons, [14] and hyperbolic metamaterials. [15,16] At the same time, the hyperlens [17][18][19][20][21] as far-field super-resolution lens was also designed by hyperbolic metamaterials which can convert the near-field evanescent waves to the far-filed propagating waves.…”

“…The analytical results of super-resolution imaging agree well with the numerical results. In addition, due to the impedance mismatching between SICSL and the air interface, the whispering gallery modes (WGMs) [11] are excited and affect the imaging quality. We clarify the relation between the resolution and exciting WGMs by solving the eigen equations of SICSL.…”

Improving resolution of superlens based on solid immersion mechanism

“…One of the main issues lies on the role of wave drain/sink and how it contributes to subwavelength imaging. Furthermore, a recent experiment in liquid setup provides further insights on super-resolution to which evanescent waves other than wave drains may contribute [24]. Before coming to the numerical results, we remark on the super-resolution and wave drain to clarify our simulation setup.…”

Role played by port drains in a Maxwell fish-eye lens

“…Gradient refractive index (GRI) lens has been developed rapidly for its excellent capability to control the propagation of electromagnetic waves [29][30][31][32][33] and enable focusing or imaging. [34][35][36][37][38][39][40][41] Among these GRI lenses, the Mikaelian lens (ML) as a self-focusing cylindrical medium was derived firstly by Mikaelian in 1951 [42] and has drawn much attention, due to its property of self-imaging in geometrical optics. [43,44] Many applications based on the Mikaelian lens were designed and fabricated from microwave frequency to optical frequency.…”

Near-field multiple super-resolution imaging from Mikaelian lens to generalized Maxwell’s fish-eye lens