“The metasurface is made of a lattice of metallic sesquialteral (one and a half pitch) helical particles,” the researchers explain. “Each particle contains six rectangular bars arranged in a series one above the another creating a spiral. The proposed metasurface exhibits a dual-band asymmetric transmission accompanied by the effect of a complete polarization conversion in the response on the particular distributions of currents induced in the particle’s bars by an incident wave. Regarding circularly polarized waves the metasurface demonstrates a strong circular dichroism.”
An optical diode, the researchers continue, is a device transmitting light in one direction and blocking it in the reverse direction. Among various types of optical diodes, one well-known example of this non-reciprocal response is “the magnetooptical (Faraday) effect related to circularly polarized light propagating in gyrotropic materials.”
“The biased magnetic field breaks the time-reversal symmetry, which leads to a nonreciprocal response of media,” the researchers state. “This mechanism is accompanied by the effect of circular dichroism related to differential absorption of the left-handed and right-handed circularly polarized waves. However, the nonreciprocal response is not restricted to the use of magnetic field only. Indeed, optical diodes can be constructed by utilizing spatial-temporal modulations of refractive indices or some nonlinear effects for which the reciprocity theorem is violated.”
Alternatively, they add, an asymmetric transmission can be realized in chiral artificial structures, or metamaterials, even when they are completely reciprocal. There are limitations to chiral metamaterials based on 2D planar technologies, however. The first limitation is related to their electromagnetic properties, considering that a complete asymmetric transmission is a resonant feature strongly dependent on dissipation. The second limitation is that commercial glass epoxy laminates cannot provide mechanical support of metallic patterns at extremely high temperatures, which restricts their application area.
“We argue that a complete polarization conversion can be reached by solving a geometrical optimization problem for the required frequency band,” the researchers conclude. “In such a way, our work paves the way to find an industrially high-temperature component solution on polarization conversion an separating communication channels utilizing features of the linear asymmetric transmission and strong circular dichroism at microwaves as well as at higher frequencies.”
Authors of the paper include Shengzhe Wu, Su Xu, Tatiana L. Zinenko, Vladimir V. Yachin, Sergey L. Prosvirnin and Vladimir R. Tuz.
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