Ali Farhan, Aksu Serap
Department of Physics, Bilkent University, Ankara 06800, Turkey.
Department of Physics, Koc University, Istanbul 34450, Turkey.
Materials (Basel). 2020 Nov 14;13(22):5140. doi: 10.3390/ma13225140.
We theoretically investigate a multi-resonant plasmonic metamaterial perfect absorber operating between 600 and 950 nm wavelengths. The presented device generates 100% absorption at two resonance wavelengths and delivers an ultra-narrow band (sub-20 nm) and high quality factor (Q=44) resonance. The studied perfect absorber is a metal-insulator-metal configuration where a thin MgF2 spacer is sandwiched between an optically thick gold layer and uniformly patterned gold circular nanodisc antennas. The localized and propagating nature of the plasmonic resonances are characterized and confirmed theoretically. The origin of the perfect absorption is investigated using the impedance matching and critical coupling phenomenon. We calculate the effective impedance of the perfect absorber and confirm the matching with the free space impedance. We also investigate the scattering properties of the top antenna layer and confirm the minimized reflection at resonance wavelengths by calculating the absorption and scattering cross sections. The excitation of plasmonic resonances boost the near-field intensity by three orders of magnitude which enhances the interaction between the metamaterial surface and the incident energy. The refractive index sensitivity of the perfect absorber could go as high as S=500 nm/RIU. The presented optical characteristics make the proposed narrow-band multi-resonant perfect absorber a favorable platform for biosensing and contrast agent based bioimaging.
我们从理论上研究了一种在600至950纳米波长之间工作的多共振等离子体超材料完美吸收体。所展示的器件在两个共振波长处产生100%的吸收,并呈现出超窄带(低于20纳米)和高品质因数(Q = 44)的共振。所研究的完美吸收体采用金属-绝缘体-金属结构,其中一层薄的MgF₂间隔层夹在一层光学厚度较大的金层和均匀图案化的金圆形纳米盘天线之间。从理论上对等离子体共振的局域和传播特性进行了表征和确认。利用阻抗匹配和临界耦合现象研究了完美吸收的起源。我们计算了完美吸收体的有效阻抗,并确认其与自由空间阻抗相匹配。我们还研究了顶部天线层的散射特性,并通过计算吸收和散射横截面确认了在共振波长处反射最小。等离子体共振的激发将近场强度提高了三个数量级,这增强了超材料表面与入射能量之间的相互作用。完美吸收体的折射率灵敏度可达S = 500纳米/RIU。所展示的光学特性使所提出的窄带多共振完美吸收体成为用于生物传感和基于造影剂的生物成像的理想平台。