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Your search keyword '"Yan, Xicheng"' showing total 26 results
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26 results on '"Yan, Xicheng"'

1. Approaching perfect absorption of monolayer molybdenum disulfide at visible wavelengths using critical coupling

Author

Jiang, Xiaoyun, Wang, Tao, Xiao, Shuyuan, Yan, Xicheng, Cheng, Le, and Zhong, Qingfang

Subjects
Physics - Optics
Abstract

A simple perfect absorption structure is proposed to achieve the high efficiency light absorption of monolayer molybdenum disulfide (MoS 2 ) by the critical coupling mechanism of guided resonances. The results of numerical simulation and theoretical analysis show that the light absorption in this atomically thin layer can be as high as 98 . 3% at the visible wavelengths, which is over 12 times more than that of a bare monolayer MoS 2 . In addition, the operating wavelength can be tuned flexibly by adjusting the radius of the air hole and the thickness of the dielectric layers, which is of great practical significance to improve the efficiency and selectivity of the absorption in monolayer MoS 2 . The novel idea of using critical coupling to enhance the light-MoS 2 interaction can be also adopted in other atomically thin materials. And the meaningful improvement and tunability of the absorption in monolayer MoS 2 provide a good prospect for the realization of high-performance MoS 2 -based optoelectronic applications, such as photodetection and photoluminescence.

Published
2018
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2. Injection height impact on combustion instability in a centrally staged combustor.

Author

Wang, Jianchen, Yan, Xicheng, Wang, Xinyao, Han, Meng, Wang, Yuzhuo, Han, Xiao, and Zhang, Chi

Subjects
*COMBUSTION chambers, *COMBUSTION, *OSCILLATIONS, *POLLUTANTS, *FLAME
Abstract

Centrally staged lean premixed pre-vaporized (LPP) combustors are widely applied in aeroengines to reduce pollutant emissions. However, combustion instability represents a critical challenge in the development of it. In the centrally staged combustor, injection height is defined as the injector-wall distance of the main stage. The partially premixed swirling combustor was built to study the effect of injection height on combustion instability, and several schemes under various conditions were investigated. Spray fields corresponding to different configurations were measured in cold flow, and reactive experiments were conducted in different equivalence ratios of the main stage ( φ m ). The results indicate that combustion instability occurred in conjunction with stratified flames. The injection height mainly affected the amplitude of the combustion instability. It affected the heat release fluctuations and the phase difference between the heat release and pressure fluctuations by influencing the flame structure, which finally affected the oscillation. Dynamic mode decomposition analysis showed that oscillations in three cases occurred within the axial modes; however, a reduction in injection height slightly decreased the resonant frequency. These results have rarely been reported in previous work and may provide useful ideas for designing LPP combustors. [ABSTRACT FROM AUTHOR]

Published
2025
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3. Tunable light trapping and absorption enhancement with graphene-based complementary metamaterials

Author

Xiao, Shuyuan, Wang, Tao, Liu, Tingting, Zhou, Chaobiao, Jiang, Xiaoyun, Yan, Xicheng, Cheng, Le, and Xu, Chen

Subjects
Physics - Optics
Abstract

Surface plasmon resonance (SPR) has been intensively investigated and widely exploited to trap the incident light and enhance absorption in the optoelectronic devices. The availability of graphene as a plasmonic material with strong half-metallicity and continuously tunable surface conductivity makes it promising to dynamically modulate the absorption enhancement with graphene-based metamaterials. Here we numerically demonstrate tunable light trapping and absorption enhancement can be realized with graphene-based complementary metamaterials. Furthermore, we also explore the polarization sensitivity in the proposed device, in which case either TM or TE plane wave at the specific wavelength can be efficiently absorbed by simply manipulating the Fermi energy of graphene. Therefore, this work can find potential applications in the next generation of photodetectors with tunable spectral and polarization selectivity in the mid-infrared and terahertz (THz) regimes.

Published
2017
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4. Tunable ultra-high-efficiency light absorption of monolayer graphene using critical coupling with guided resonance

Author

Jiang, Xiaoyun, Wang, Tao, Xiao, Shuyuan, Yan, Xicheng, and Cheng, Le

Subjects
Physics - Optics
Abstract

We numerically demonstrate a novel monolayer graphene-based perfect absorption multi-layer photonic structure by the mechanism of critical coupling with guided resonance, in which the absorption of graphene can significantly close to 99% at telecommunication wavelengths. The highly efficient absorption and spectral selectivity can be obtained with designing structural parameters in the near infrared ranges. Compared to previous works, we achieve the complete absorption of single-atomic-layer graphene in the perfect absorber for the first time, which not only opens up new methods of enhancing the light-graphene interaction, but also makes for practical applications in high-performance optoelectronic devices, such as modulators and sensors.

Published
2017
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5. Active modulation of electromagnetically induced transparency analogue in terahertz hybrid metal-graphene metamaterials

Author

Xiao, Shuyuan, Wang, Tao, Liu, Tingting, Yan, Xicheng, Li, Zhong, and Xu, Chen

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Metamaterial analogues of electromagnetically induced transparency (EIT) have been intensively studied and widely employed for slow light and enhanced nonlinear effects. In particular, the active modulation of the EIT analogue and well-controlled group delay in metamaterials have shown great prospects in optical communication networks. Previous studies have focused on the optical control of the EIT analogue by integrating the photoactive materials into the unit cell, however, the response time is limited by the recovery time of the excited carriers in these bulk materials. Graphene has recently emerged as an exceptional optoelectronic material. It shows an ultrafast relaxation time on the order of picosecond and its conductivity can be tuned via manipulating the Fermi energy. Here we integrate a monolayer graphene into metal-based terahertz (THz) metamaterials, and realize a complete modulation in the resonance strength of the EIT analogue at the accessible Fermi energy. The physical mechanism lies in the active tuning the damping rate of the dark mode resonator through the recombination effect of the conductive graphene. Note that the monolayer morphology in our work is easier to fabricate and manipulate than isolated fashion. This work presents a novel modulation strategy of the EIT analogue in the hybrid metamaterials, and pave the way towards designing very compact slow light devices to meet future demand of ultrafast optical signal processing.

Published
2017
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6. Strong interaction between graphene layer and Fano resonance in terahertz metamaterials

Author

Xiao, Shuyuan, Wang, Tao, Jiang, Xiaoyun, Yan, Xicheng, Cheng, Le, Wang, Boyun, and Xu, Chen

Subjects
Physics - Optics
Abstract

Graphene has emerged as a promising building block in the modern optics and optoelectronics due to its novel optical and electrical properties. In the mid-infrared and terahertz (THz) regime, graphene behaves like metals and supports surface plasmon resonances (SPRs). Moreover, the continuously tunable conductivity of graphene enables active SPRs and gives rise to a range of active applications. However, the interaction between graphene and metal-based resonant metamaterials has not been fully understood. In this work, a simulation investigation on the interaction between the graphene layer and THz resonances supported by the two-gap split ring metamaterials is systematically conducted. The simulation results show that the graphene layer can substantially reduce the Fano resonance and even switch it off, while leave the dipole resonance nearly unaffected, which phenomenon is well explained with the high conductivity of graphene. With the manipulation of graphene conductivity via altering its Fermi energy or layer number, the amplitude of the Fano resonance can be modulated. The tunable Fano resonance here together with the underlying physical mechanism can be strategically important in designing active metal-graphene hybrid metamaterials. In addition, the "sensitivity" to the graphene layer of the Fano resonance is also highly appreciated in the field of ultrasensitive sensing, where the novel physical mechanism can be employed in sensing other graphene-like two-dimensional (2D) materials or biomolecules with the high conductivity., Comment: Revised Manuscript

Published
2017
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7. Tunable light trapping and absorption enhancement with graphene ring arrays

Author

Xiao, Shuyuan, Wang, Tao, Liu, Yuebo, Xu, Chen, Han, Xu, and Yan, Xicheng

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Surface plasmon resonance (SPR) has been intensively studied and widely employed for light trapping and absorption enhancement. In the mid-infrared and terahertz (THz) regime, graphene supports the tunable SPR via manipulating its Fermi energy and enhances light-matter interaction at the selective wavelength. In this work, periodic arrays of graphene rings are proposed to introduce tunable light trapping with good angle polarization tolerance and enhance the absorption in the light-absorbing materials nearby to more than one order. Moreover, the design principle here could be set as a template to achieve multi-band plasmonic absorption enhancement by introducing more graphene concentric rings into each unit cell. This work not only opens up new ways of employing graphene SPR, but also leads to practical applications in high-performance simultaneous multi-color photodetection with high efficiency and tunable spectral selectivity.

Published
2016
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8. An ultrasensitive and multispectral refractive index sensor design based on quad-supercell metamaterials

Author

Xiao, Shuyuan, Wang, Tao, Liu, Yuebo, Han, Xu, and Yan, Xicheng

Subjects
Physics - Optics
Abstract

Plasmonic metamaterials support the localized surface plasmon resonance (LSPR), which is sensitive to the change in the dielectric environment and highly desirable for ultrasensitive biochemical sensing. In this work, a novel design of supercell metamaterials of four mutually rotating split ring resonators (SRRs) is proposed, where simultaneous excitations of odd (N=1 and N = 3) and even (N=2) resonance modes are realized due to additional asymmetry from the rotation and show insensitivity to two orthogonal polarizations. The full utilization of these three resonance dips show bright prospects for multispectral application. As a refractive index (RI) sensor, ultrahigh sensitivities ~1000nm/RIU for LC mode (N=1) and ~500nm/RIU for plasmon mode (N=2) are obtained in near infrared (NIR) spectrum., Comment: Accepted Manuscript

Published
2015
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26. An Ultrasensitive and Multispectral Refractive Index Sensor Design Based on Quad-Supercell Metamaterials.

Author

Xiao, Shuyuan, Wang, Tao, Liu, Yuebo, Han, Xu, and Yan, Xicheng

Subjects
PLASMONICS, METAMATERIALS, SURFACE plasmon resonance, ASYMMETRY (Chemistry), POLARIZATION spectroscopy
Abstract

Plasmonic metamaterials support the localized surface plasmon resonance (LSPR), which is sensitive to the change in the dielectric environment and highly desirable for ultrasensitive biochemical sensing. In this work, a novel design of supercell metamaterials of four mutually rotating split ring resonators (SRRs) is proposed, where simultaneous excitations of odd ( N = 1 and N = 3) and even ( N = 2) resonance modes are realized due to additional asymmetry from the rotation and show insensitivity to two orthogonal polarizations. The full utilization of these three resonance dips show bright prospects for multispectral application. As a refractive index (RI) sensor, ultrahigh sensitivities ∼1000 nm/RIU for LC mode ( N = 1) and ∼500 nm/RIU for plasmon mode ( N = 2) are obtained in the near infrared (NIR) spectrum. [ABSTRACT FROM AUTHOR]

Published
2017
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