Frequency Reconfigurable and Multifunctional Metastructure Regulated by Nematic Liquid Crystal: Broadband Circular to Linear Polarization Converter

Abstract: With the tunability of the nematic liquid crystal (NLC), a broadband frequency reconfigurable and versatile metastructure (MS) is proposed and theoretically investigated in this paper, combining circular‐to‐linear (CTL) polarization conversion (PC) and circular‐to‐circular (CTC) PC simultaneously. The MS is composed of two via‐coupled modules, which can respond differently to the incident waves. Each module is connected utilizing a metal via a column, thus exceedingly enhancing the energy transmission and redu… Show more

“…To achieve dynamic control over the functionality of MMs, a variety of different schemes have been suggested by integrating active media in MM systems, such as superconductors, 18 semiconductors, 19,20 two-dimensional materials, 21–23 liquid crystals, 24–26 microelectromechanical systems, 27 and so on. As an alternative active material, phase-change materials have attracted great interest due to their direct control through external fields.…”

Switchable asymmetric transmission with broadband polarization conversion in vanadium dioxide-assisted terahertz metamaterials

“…To achieve dynamic control over the functionality of MMs, a variety of different schemes have been suggested by integrating active media in MM systems, such as superconductors, 18 semiconductors, 19,20 two-dimensional materials, 21–23 liquid crystals, 24–26 microelectromechanical systems, 27 and so on. As an alternative active material, phase-change materials have attracted great interest due to their direct control through external fields.…”

Switchable asymmetric transmission with broadband polarization conversion in vanadium dioxide-assisted terahertz metamaterials

“…Gallium arsenide (GaAs) photoconductive semiconductor switch (PCSS) is a new type of solid-state device, that combines ultrafast laser with photoelectric semiconductor [1][2][3]. As one of the most promising high-power closing switches, it has drawn wide attention in the fields of highpower microwave generation and pulsed power technology, due to its many inherent advantages such as ultrafast switching, high power, low time jitter and compact structure [4][5][6].…”

Effects of spot size on the operation mode of GaAs photoconductive semiconductor switch employing extrinsic photoconductivity

“…The excessive use of fossil fuels in various sectors, such as the automobile, space industry, and agriculture, has created enormous concerns about their depletion, which forced researchers to think of alternative clean energy sources to reduce the dependency on fossil fuels and create the way toward futuristic sustainable, eco-friendly, and emission-free energy sources . Hydrogen (H 2 ) energy is considered an immensely auspicious and sustainable energy source because of its emission-free nature, abundant raw source, and high energy density of ∼287 kJ mol –1 . , H 2 energy is extensively used for industrial purposes such as petroleum refining and synthesis of ammonia and methanol as well as exploring its vast market and competition in the futuristic fuel cell-based vehicles for transportation. , Among numerous approaches, electrocatalytic water splitting is the utmost exciting, facile, and practical pathway compared with other methods due to its low cost and high-purity generation of clean and green hydrogen energy and oxygen during hydrogen and oxygen evolution reactions. , However, it offers a large overpotential in alkaline medium, which limits the development of scalable hydrogen energy production, making it expensive due to the intake of high electric energy. , On the other hand, the energy-saving electrocatalyst can stimulate proton reduction reaction at low overpotentials and Tafel slopes with improved reaction kinetics. , Basically, the catalysts’ electrocatalytic performance exclusively depends on available active centers, the inherent properties of active centers, and mass transport properties . Therefore, it is extremely desirable to cultivate high-standard electrocatalysts that are bifunctional for hydrogen and oxygen generation with exclusive merits such as excellent electronic transport properties, exceptional intrinsic activities, inexpensive, highly available active centers, and high stability in an alkaline medium.…”

“…4,5 Among numerous approaches, electrocatalytic water splitting is the utmost exciting, facile, and practical pathway compared with other methods due to its low cost and high-purity generation of clean and green hydrogen energy and oxygen during hydrogen and oxygen evolution reactions. 6,7 However, it offers a large overpotential in alkaline medium, which limits the development of scalable hydrogen energy production, making it expensive due to the intake of high electric energy. 8,9 On the other hand, the energy-saving electrocatalyst can stimulate proton reduction reaction at low overpotentials and Tafel slopes with improved reaction kinetics.…”

Unveiling the Transformative Potential of SWCNT/In₂O₃ Heterostructures as High-Performance Catalysts for Overall Water Splitting