Xiaocan Xu scite author profile

Xiaocan Xu

5Publications

72Citation Statements Received

124Citation Statements Given

How they've been cited

250

How they cite others

213

124

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Sun Yat-sen University

Publications

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Actively logical modulation of MEMS-based terahertz metamaterial

Yang

et al. 2021

Photon. Res.

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The integration of micro-electro-mechanical system (MEMS) with metamaterial has provided a novel route to achieve programmability via its reconfigurable capabilities. Here, we propose and demonstrate a MEMS-based metadevice by using switchable winding-shaped cantilever metamaterial (WCM) for active logical modulation. WCM can be actuated by external driving voltage, and the logical modulation bit is performed by releasing MEMS cantilevers to represent “on” and “off” states. While the underneath substrate surface of a MEMS-based metadevice is rough after releasing the cantilevers, the metadevice is allowed to operate on the reconfigurable switching state and avoid the snapping down of the device when the system is overloaded. Such a reconfigurable and programmable MEMS-based metadevice exhibits multifunctional characteristics to simultaneously perform the logic operations of “OR” and “AND” gates. By exploiting the tuning mechanism of the MEMS-based metadevice, the arbitrary metamaterial configuration can be implanted into WCM. This opens a wide avenue to further enlarge the operating frequency range and applications in optoelectronic fields. These unique results provide various possibilities in multifunctional switching, active logical modulating, and optical computing applications.

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A voltage-controllable VO₂ based metamaterial perfect absorber for CO₂ gas sensing application

Lin

2022

Nanoscale

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Tunable Terahertz Metamaterial with Electromagnetically Induced Transparency Characteristic for Sensing Application

Zhong

Lin

2021

Nanomaterials

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We present and demonstrate a MEMS-based tunable terahertz metamaterial (TTM) composed of inner triadius and outer electric split-ring resonator (eSRR) structures. With the aim to explore the electromagnetic responses of TTM device, different geometrical parameters are compared and discussed to optimize the suitable TTM design, including the length, radius, and height of TTM device. The height of triadius structure could be changed by using MEMS technique to perform active tunability. TTM shows the polarization-dependent and electromagnetic induced transparency (EIT) characteristics owing to the eSRR configuration. The electromagnetic responses of TTM exhibit tunable characteristics in resonance, polarization-dependent, and electromagnetically induced transparency (EIT). By properly tailoring the length and height of the inner triadius structure and the radius of the outer eSRR structure, the corresponding resonance tuning range reaches 0.32 THz. In addition to the above optical characteristics of TTM, we further investigate its potential application in a refraction index sensor. TTM is exposed on the surrounding ambient with different refraction indexes. The corresponding key sensing performances, such as figure of merit (FOM), sensitivity (S), and quality factor (Q-factor) values, are calculated and discussed, respectively. The calculated sensitivity of TTM is 0.379 THz/RIU, while the average values of Q-factor and FOM are 66.01 and 63.83, respectively. These characteristics indicate that the presented MEMS-based TTM device could be widely used in tunable filters, perfect absorbers, high-efficient environmental sensors, and optical switches applications for THz-wave optoelectronics.

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Tunable Terahertz Free Spectra Range Using Electric Split-Ring Metamaterial

Lin

2021

J. Microelectromech. Syst.

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Electrothermally tunable terahertz cross-shaped metamaterial for opto-logic operation characteristics

Lin

2022

iScience

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Xiaocan Xu

Actively logical modulation of MEMS-based terahertz metamaterial

A voltage-controllable VO₂ based metamaterial perfect absorber for CO₂ gas sensing application

Tunable Terahertz Metamaterial with Electromagnetically Induced Transparency Characteristic for Sensing Application

Tunable Terahertz Free Spectra Range Using Electric Split-Ring Metamaterial

Electrothermally tunable terahertz cross-shaped metamaterial for opto-logic operation characteristics

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Xiaocan Xu

Actively logical modulation of MEMS-based terahertz metamaterial

A voltage-controllable VO2 based metamaterial perfect absorber for CO2 gas sensing application

Tunable Terahertz Metamaterial with Electromagnetically Induced Transparency Characteristic for Sensing Application

Tunable Terahertz Free Spectra Range Using Electric Split-Ring Metamaterial

Electrothermally tunable terahertz cross-shaped metamaterial for opto-logic operation characteristics

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A voltage-controllable VO₂ based metamaterial perfect absorber for CO₂ gas sensing application