Multifunctional Hybrid Metasurfaces for Dynamic Tuning of Terahertz Waves

Cai, Honglei; Shi, Chen; Zou, Chongwen; Huang, Qiuping; Liu, Yu; Hu, Xiang; Fu, Zhengping; Zhao, Yi; He, Hongchuan; Lu, Yalin

doi:10.1002/adom.201800257

Cited by 112 publications

(94 citation statements)

References 43 publications

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“…Furthermore, these active materials are usually responsive to a single driving field, one of electrical, thermal, or optical stimulus, which hinders their applicability for multidimensional manipulation of terahertz waves. Phase change materials with contrasting material properties at different crystallographic phases would be an ideal material platform for the realization of multifunctional terahertz metadevices . The most popular choice among phase change materials for terahertz metadevices has been vanadium dioxide (VO 2 ), which has been exploited for varied functionalities enabled by its hysteretic insulator to metal phase transition .…”

mentioning

confidence: 99%

“…The most popular choice among phase change materials for terahertz metadevices has been vanadium dioxide (VO 2 ), which has been exploited for varied functionalities enabled by its hysteretic insulator to metal phase transition . However, the practical applicability of VO 2 for terahertz metadevices is hindered by its limited multilevel response, nonvolatility at elevated temperature, predefined singular ultrafast optical response, and complexity of fabrication …”

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confidence: 99%

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Chalcogenide Phase Change Material for Active Terahertz Photonics

et al. 2019

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The terahertz part of the electromagnetic spectrum possesses numerous promising applications such as high-speed wireless communication, security screening, chemical identification, and nondestructive biosensing. [1] However, the terahertz spectral region has remained technologically uncharted, due to the lack of efficient devices to generate, manipulate, and detect terahertz waves. In the past decade, there has been a significant progress in active control of terahertz waves using metamaterials integratedThe strikingly contrasting optical properties of various phases of chalcogenide phase change materials (PCM) has recently led to the development of novel photonic devices such as all-optical non-von Neumann memory, nanopixel displays, color rendering, and reconfigurable nanoplasmonics. However, the exploration of chalcogenide photonics is currently limited to optical and infrared frequencies. Here, a phase change material integrated terahertz metamaterial for multilevel nonvolatile resonance switching with spatial and temporal selectivity is demonstrated. By controlling the crystalline proportion of the PCM film, multilevel, non-volatile, terahertz resonance switching states with long retention time at zero hold power are realized. Spatially selective reconfiguration at submetamaterial scale is shown by delivering electrical stimulus locally through designer interconnect architecture. The PCM metamaterial also features ultrafast optical modulation of terahertz resonances with tunable switching speed based on the crystalline order of the PCM film. The multilevel nonvolatile, spatially selective, and temporally tunable PCM metamaterial will provide a pathway toward development of novel and disruptive terahertz technologies including spatio-temporal terahertz modulators for high speed wireless communication, neuromorphic photonics, and machine-learning metamaterials.

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Chalcogenide Phase Change Material for Active Terahertz Photonics

et al. 2019

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“…[76,81,[86][87][88][89][90][91][92][93][94][95][96][97][98][99] The early demonstration of a THz metamaterial made of VO 2 involved an array of cut-wire-type resonators without any metal structures (Figure 7a). Instead of thin films, small pieces of VO 2 are integrated into metamaterial designs as a part of resonators so that the resonance properties can be directly tuned by controlling the IMT.…”

Section: Thermally Controlled Devicesmentioning

confidence: 99%

“…[96] When asymmetric SRRs whose two gaps are filled with VO 2 are connected in parallel (Figure 8a), the resonance peak can be redshifted by applying a current ( Figure 8b). [96] When asymmetric SRRs whose two gaps are filled with VO 2 are connected in parallel (Figure 8a), the resonance peak can be redshifted by applying a current ( Figure 8b).…”

Section: Electrically and Optically Controlled Devicesmentioning

confidence: 99%

Dynamic Terahertz Plasmonics Enabled by Phase‐Change Materials

Jeong

Bahk

Kim

2019

Advanced Optical Materials

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Phase‐change phenomena have been an attractive research theme for decades due to the dynamic transition of material properties providing extraordinary capabilities for versatile optical device applications. Even at the terahertz (THz) frequency regime, phase‐change materials (PCMs) promote the development of dynamic devices, especially when combined with a plasmonic approach delivering strong field enhancement and localization. According to the design of plasmonic metamaterials or hybrid composites, PCMs can actively modulate the electromagnetic properties of THz waves through thermal, electrical, and optical means. In turn, THz waves can affect the PCM properties in the nonlinear regime due to the intense field strength enhancement by plasmonic structures. Here, a few types of PCMs demonstrating promising potential in THz plasmonic applications are introduced. Starting from the best‐known transition metal oxide, vanadium dioxide (VO2), which possesses an insulator‐to‐metal phase transition near room temperature, superconductors, chalcogenides, ferroelectrics, liquid crystals, and liquid metals are covered along with their phase‐change properties and the control mechanisms infused with THz plasmonic applications. The corresponding recent progress presenting how PCMs combined with plasmonic structures can demonstrate effective THz modulation is reviewed. This general overview may provide a better understanding of dynamic THz plasmonics and new ideas for future THz technology.

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“…This phase change property can be triggered on a sub-picosecond timescale by different external conditions, including temperature, stress, electromagnetic field, light, etc [28][29][30]. Due to its unique property, it is potential for the design of logic storage devices [31,32], switching devices [33,34], modulators [35,36] and many other devices. Utilizing this material, the transmission of electromagnetic waves can be continuously and spontaneously tuned by means of temperature control over a wide spectral range, and thus VO 2 gives rise to great possibilities in the field of electromagnetic wave modulation and switching devices.…”

Section: Introductionmentioning

confidence: 99%

Terahertz transmission properties of vanadium dioxide films deposited on gold grating structure with different periods

Gao

Luo

et al. 2020

Mater. Res. Express

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Vanadium dioxide (VO 2 ) is a typical thermal induced phase transition material, exhibiting a transition from metallic phase at high temperature to insulating phase at low temperature, which is also accompanied by a conductivity change of over several orders of magnitude. The transition property makes VO 2 prominent to achieve an effective degree of control of terahertz (THz) wave. In this paper, composite films consisting of metal grating with different periods and VO 2 film were prepared by polymer assisted deposition method. Although the conductivity change of VO 2 films deposited on gold grating structure across phase transition was declined to about two orders of magnitude, the amplitude modulation depth of THz of the composite films can still reach a high value. Furthermore, it was found that the THz modulation depth was related with the grating period. According to theoretical simulation, the fluctuation height of VO 2 films, caused by metal grating structure during growth, can be used to regulate THz wave. These results demonstrate an economic and unsophisticated method to fabricate VO 2 films with thickness fluctuation structure and then tune the THz waves.

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Multifunctional Hybrid Metasurfaces for Dynamic Tuning of Terahertz Waves

Cited by 112 publications

References 43 publications

Chalcogenide Phase Change Material for Active Terahertz Photonics

Chalcogenide Phase Change Material for Active Terahertz Photonics

Dynamic Terahertz Plasmonics Enabled by Phase‐Change Materials

Terahertz transmission properties of vanadium dioxide films deposited on gold grating structure with different periods

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