Abstract
Active meta polarizers based on phase-change materials have recently led to emerging developments in terahertz devices and systems for imaging, security, and high-speed communications. Existing technologies of adaptive control of meta polarizers are limited to the complexity of external stimuli. Here, we introduce an active terahertz polarizer consisting of a single layer of large array patterns of vanadium dioxide material integrated with metallic patch matrix to dynamically reconfigure the polarization of the terahertz waves. The proposed active polarizer is simple in structure and can independently manipulate the polarization of the incident THz waves in two orthogonal directions. In addition, the device can also be performing as a highly efficient reflector at the same frequencies. We demonstrate that efficient and fast polarization changes of THz waves can be achieved over a wide operating bandwidth. Compared with other active polarizers using mechanical, optical and thermal controls, it can be conveniently manipulated with DC bias without any external actuators, intense laser source or heater. Therefore, with the advantages of high efficiency, compact size, low loss, low cost and fast response, the proposed polarizer can be highly integrative and practical to operate within adaptive terahertz circuits and systems.
Highlights
Active meta polarizers based on phase-change materials have recently led to emerging developments in terahertz devices and systems for imaging, security, and high-speed communications
Active polarizers play an important role in terahertz imaging and wireless communication systems, which are essential for improving imaging and communication qualities[6,7]
Recent technologies of adaptive control of propagating terahertz wave polarizations are based on meta-devices which modify their intrinsic overall topology through mechanical, optical, electrical and thermal s timuli[8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33]
Summary
Active meta polarizers based on phase-change materials have recently led to emerging developments in terahertz devices and systems for imaging, security, and high-speed communications. With the advantages of high efficiency, compact size, low loss, low cost and fast response, the proposed polarizer can be highly integrative and practical to operate within adaptive terahertz circuits and systems Terahertz radiations, with their extraordinary advantages (large bandwidth, traveling in a line of sight, good penetration and non-ionizing) offer unprecedented capabilities in applications spanning from medical imaging1, security2, radar[3], high-speed c ommunications[4] to spectroscopy of complex molecular n etworks[5]. Different other optical approaches use shadow masks[18] or programable photo patterns[19] to project intense light on Si substrates for manipulating the polarization of the THz incident wave These approaches show a higher degree of flexibility, they require external intense laser sources, which are increasing the size of the overall polarizer device.
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