Tunable magnetic metamaterial based multi-split-ring resonator (MSRR) using MEMS switch components

He, Xiaodong; Lv, Zhiqiu; Liu, Bo; Li, Zhihong

doi:10.1007/s00542-011-1313-z

Cited by 12 publications

(7 citation statements)

References 22 publications

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“…On the contrary, metamaterials can be rationally designed to achieve optical anisotropy910111213141516171819 that can also be altered by changing the refractive index of the surrounding medium20212223 or by emplying electrical or thermal effects in liquid crystals2425. At the same time, substantial progress has been possible in developing metamaterials with unit cells reconfigurable with micro-actuators26272829303132333435. Here we report the active control of anisotropy in the terahertz spectral region in a metamaterial array of Maltese crosses driven by micro-actuators.…”

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confidence: 99%

Microelectromechanical Maltese-cross metamaterial with tunable terahertz anisotropy

et al. 2012

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Dichroic polarizers and waveplates exploiting anisotropic materials have vast applications in displays and numerous optical components, such as filters, beamsplitters and isolators. Artificial anisotropic media were recently suggested for the realization of negative refraction, cloaking, hyperlenses, and controlling luminescence. However, extending these applications into the terahertz domain is hampered by a lack of natural anisotropic media, while artificial metamaterials offer a strong engineered anisotropic response. Here we demonstrate a terahertz metamaterial with anisotropy tunable from positive to negative values. It is based on the Maltese-cross pattern, where anisotropy is induced by breaking the four-fold symmetry of the cross by displacing one of its beams. The symmetry breaking permits the excitation of a Fano mode active for one of the polarization eigenstates controlled by actuators using microelectromechanical systems. The metamaterial offers new opportunities for the development of terahertz variable waveplates, tunable filters and polarimetry.

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confidence: 99%

Microelectromechanical Maltese-cross metamaterial with tunable terahertz anisotropy

et al. 2012

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“…Engagement of the Coulomb force (Box 1a) allows for the development of membrane-based metamaterials controlled by electric signals, which work in the visible and near-infrared spectral bands 65 . They are orders of magnitude faster and far more compact than previously reported electrically reconfigurable THz MEMS comb-drive metamaterials ( Figure 2b) and provide a much higher degree of control than metamaterials with opaque adjustable ground plane designs [27][28][29][30][31][32][33][34][35][36][37] . Furthermore, the membrane-based metamaterials can be used in transmission and reflection modes.…”

Section: Electrostatic Actuationmentioning

confidence: 77%

“…This new high-throughput and silicon compatible technology benefits from related advances in nano-opto-mechanics 3 , which have led to the demonstration of thermally driven plasmonic nano-mechanical oscillators 4,5 and resonators 6 . It is being developed alongside other approaches for creating nonlinear, tuneable and switchable metamaterials from the microwave to the optical parts of the spectrum such as the phase change [7][8][9] and liquid crystal [10][11][12][13] hybrid metamaterial technologies, coherent control [14][15][16][17][18][19] , structural reconfiguration 20,21 of metamaterials based on stretchable polymer substrates [22][23][24][25][26] , MEMS [27][28][29][30][31][32][33][34][35][36][37] , microfluidics 38,39 and magnetic forces 40,41 ; carrier injection in semiconductor metamaterial substrates 42,43 and graphene 44,45 ; and superconducting metamaterials 46,47 . A comprehensive overview of these approaches is available in recent reviews 1,…”

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confidence: 99%

Reconfigurable nanomechanical photonic metamaterials

2016

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Video file:FIB_Fabrication.mov Title:Focused ion beam fabrication of an array of metamaterial samples Description:Prototyping membrane reconfigurable metamaterial. Focused ion beam (FIB) milling is used to pattern a 4 x 4 array of metamaterial samples on pre-fabricated gold patches supported by a silicon nitride membrane of 50 nm thickness. Milling includes patterning of the gold film and cutting through the silicon nitride membrane, where appropriate. The video, which has been recorded by scanning electron microscopy (SEM), is compressed to a few seconds while the total FIB milling time is about 22 minutes. Video courtesy of Jun-Yu Ou.Video file: Actuating_Chevron_Metamaterial.mov Title:Actuating nanomembrane chevron metamaterial Description:Chevron nanowire array fabricated on a silicon nitride nanomembrane. To show reconfiguration of the metamaterial every second chevron nanowire is heated by electrical current running through the nanowire and heated nanowires bend due to differential thermal expansion of the gold and silicon nitride layers that make up the nanowires. The SEM video shows the central part of the array with alternating nanowires moving from the plane of the array. Actuation of the metamaterial is seen at a viewing angle of 30° while the total applied current is increased from zero to +7 mA and then reduced via zero to -7 mA and finally returned to zero. The same structure can also be driven by the magnetic Lorentz force acting on current-carrying nanowires when an external magnetic field that is oriented perpendicular to the current flow is applied. Note that SEM imaging of nanowire actuation driven by the Lorentz force is impossible, as the required static magnetic field would interfere with the scanning electron microscope. Video courtesy of João P. Valente.Video file: Electrostatic_Metamaterial_Switch.mov Title:Switching nanomembrane electro-optical metamaterial with the Coulomb force Description:Irreversible switching transition of an electrostatically reconfigurable plasmonic metamaterial fabricated on a silicon nitride nanomembrane. When the driving voltage is less than the switching threshold voltage of about 3 V, the structure can be modulated in a reversible fashion. The SEM video shows that when the applied voltage increases above the threshold voltage, the plasmonic nanostructure switches irreversibly into a string-pair configuration, resulting in a dramatic change of the metamaterial's optical properties. The image drift is caused by the applied voltage. Video courtesy of Jun-Yu Ou.Video file: Random_Access_Metamaterial.mov Title:Actuating individual wires in randomly reconfigurable nanomembrane metamaterial Description:Random access reconfigurable metamaterial. An array of nanowires on a silicon nitride nanomembrane allows independent electrical actuation of each nanowire of the array. The SEM video shows how electrical current supplied to individual nanowires by a computer-controlled multi-channel digital-to-analog converter actuates the nanostructure. In this way the optical resp...

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“…The strength of the dipole–dipole coupling of these MEMEs can be continuously adjusted by fine-tuning the distance between the two rings using the MEMS’ actuators, thereby enabling efficient electromagnetic adaptation reaction. The reconfiguration of the metamolecules may enable the polarization of anisotropic metamaterial to be switched independently [ 106 , 107 , 108 , 109 ].…”

Section: Emerging Functional Metadevicesmentioning

confidence: 99%

Metamaterials and Metasurfaces: A Review from the Perspectives of Materials, Mechanisms and Advanced Metadevices

2022

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Throughout human history, the control of light, electricity and heat has evolved to become the cornerstone of various innovations and developments in electrical and electromagnetic technologies. Wireless communications, laser and computer technologies have all been achieved by altering the way light and other energy forms act naturally and how to manage them in a controlled manner. At the nanoscale, to control light and heat, matured nanostructure fabrication techniques have been developed in the last two decades, and a wide range of groundbreaking processes have been achieved. Photonic crystals, nanolithography, plasmonics phenomena and nanoparticle manipulation are the main areas where these techniques have been applied successfully and led to an emergent material sciences branch known as metamaterials. Metamaterials and functional material development strategies are focused on the structures of the matter itself, which has led to unconventional and unique electromagnetic properties through the manipulation of light—and in a more general picture the electromagnetic waves—in widespread manner. Metamaterial’s nanostructures have precise shape, geometry, size, direction and arrangement. Such configurations are impacting the electromagnetic light waves to generate novel properties that are difficult or even impossible to obtain with natural materials. This review discusses these metamaterials and metasurfaces from the perspectives of materials, mechanisms and advanced metadevices in depth, with the aim to serve as a solid reference for future works in this exciting and rapidly emerging topic.

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Tunable magnetic metamaterial based multi-split-ring resonator (MSRR) using MEMS switch components

Cited by 12 publications

References 22 publications

Microelectromechanical Maltese-cross metamaterial with tunable terahertz anisotropy

Microelectromechanical Maltese-cross metamaterial with tunable terahertz anisotropy

Reconfigurable nanomechanical photonic metamaterials

Metamaterials and Metasurfaces: A Review from the Perspectives of Materials, Mechanisms and Advanced Metadevices

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