We propose and demonstrate a multifunctional location-dependent metamaterial in the terahertz(THz) range in which the unit cell consists of two pairs of coupled resonators. Experimental and simulation results of our d...We propose and demonstrate a multifunctional location-dependent metamaterial in the terahertz(THz) range in which the unit cell consists of two pairs of coupled resonators. Experimental and simulation results of our devices reveal that both pairs of the coupled resonators will keep their individual resonance modes when they join together. Thus, the overall transmission spectrum is a combination of frequency response spectra of its corresponding constituent parts. While changing the locations of the inner resonators in our structure, controllable width of transmission window and changeable number of transmission dips can be realized. Our design provides a feasible structure for multifunctional microelectromechanical devices.展开更多
基金supported in part by the National Natural Science Foundation of China under Grant 61205095the Shanghai Young College Teacher Develop funding schemes under Grant slg11006the Leading Academic Discipline Project of Shanghai Municipal Government under Grant S30502
文摘We propose and demonstrate a multifunctional location-dependent metamaterial in the terahertz(THz) range in which the unit cell consists of two pairs of coupled resonators. Experimental and simulation results of our devices reveal that both pairs of the coupled resonators will keep their individual resonance modes when they join together. Thus, the overall transmission spectrum is a combination of frequency response spectra of its corresponding constituent parts. While changing the locations of the inner resonators in our structure, controllable width of transmission window and changeable number of transmission dips can be realized. Our design provides a feasible structure for multifunctional microelectromechanical devices.
