Shape memory alloy-based 3D morphologically reconfigurable chiral metamaterial for tailoring circular dichroism by voltage control

Jiang, Lixin; Yuan, Qi; Li, Yongfeng; Zheng, Lin; Zhu, Zhibiao; Hao, Yang; Liang, Shuang; He, Wei; Pang, Yongqiang; Wang, Jiafu; Qu, Shaobo

doi:10.1364/prj.480979

Cited by 7 publications

(2 citation statements)

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“…A three-dimensional reconfigurable intrinsic chiral material has provided the freedom to tailor light [66]. The presented chiral resonator works for microwave regions and realizes 3D reconfigurable chirality through a morphological transformation using voltage control by introducing a heating film.…”

Section: Temperature Sensitivity Via Voltage Controlmentioning

confidence: 99%

An introduction of perovskite materials in chiral metasurfaces

Ijaz,

Khan,

Massoud

2023

Optoelectronic Devices and Integration XII

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Nature has implanted chirality in many organic molecules of living organisms that have made man think about exploiting this handedness property of the objects and coming up with exciting applications through synthetic chiral structures. In this connection, several chiral metasurface designs have been proposed with interesting optoelectronic applications, such as chiral sensing of a molecule at the zeptomole level, circularly polarized luminescence, circular dichroism, chiro-spintronics, and nonlinear optics. The perovskites' unique chirality features have led to the emerging perovskite optoelectronic area. In this regard, exploiting the novel chiral perovskite materials for optoelectronic functionalities becomes vitally important. This area of research is at a pre-mature stage. The present issues associated with perovskite semiconductors are toxicity, reproducibility, and instability. However, the expertise from physics, chemistry, and device engineering from the perovskite research community has been focusing on the basic material properties, fabrication, and characterization methods while simultaneously mitigating the present issues to get to successful commercialization. Future research opportunities related to chiral perovskite nanocrystals are versatile and intend to rationalize the exceptional potential of these low-cost materials for complicated optoelectronics applications.

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Section: Temperature Sensitivity Via Voltage Controlmentioning

confidence: 99%

An introduction of perovskite materials in chiral metasurfaces

Ijaz,

Khan,

Massoud

2023

Optoelectronic Devices and Integration XII

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“…[10] McPolin et al realized Janus dipolar sources that can be used in quantum technology through specific arrangements of nanostructures coupled to waveguide structures. [11] To achieve multifunctional integration, a common method is to use external conditions, such as sonic wave, [12] light, [13] temperature, [14] pressure, [15] voltage, [16] etc., to change the physical properties of the material, thus achieving functional switching under different environmental conditions. In the field of electronic control, liquid crystal, as an emerging popular material, can be used to control the phase and polarization of electromagnetic waves due to its anisotropy.…”

Section: Introductionmentioning

confidence: 99%

Janus Device Based on Liquid Crystal Regulation with a Large Incidence Angle: Analogous Quantum Optical Effect and Absorption

Liao,

Sui,

Chen

et al. 2023

Annalen der Physik

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In this paper, a Janus metastructure device (JMD) is proposed. The JMD design introduces asymmetric structures, which leads to the generation of analogous quantum optical effects when light is incident at large angles. Specifically, forward electromagnetic‐induced transparency (EIT) and backward narrowband absorption (NA) are achieved when light is incident along different directions, displaying Janus characteristics in the forward and backward directions. Additionally, the operating frequency of JMD can be controlled through the use of liquid crystal. Such features hold promising potential for various applications in photonic and optoelectronic fields. When the axial direction of the liquid crystal is oriented along the x‐direction, the JMD achieves a transparent window over 90% within 0.46–0.51 THz at forward incidence, and an absorption peak of 84.1% appears at 0.331 THz at backward incidence. When the axial direction is oriented along the y‐direction, the JMD achieves EIT in the range of 0.51–0.575 THz at forward incidence, and a backward absorption peak of 93.3% occurs at 0.305 THz. In addition, the performance changes at different polarization and incidence angles are presented. The mechanism of absorption generation, the method of suppressing excess absorption, and the parametric inversion of the electromagnetic characteristics of JMD are also discussed.

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