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278 results on '"Shiqiao Qin"'

1. Integrated wafer-scale ultra-flat graphene by gradient surface energy modulation

Author

Xin Gao, Liming Zheng, Fang Luo, Jun Qian, Jingyue Wang, Mingzhi Yan, Wendong Wang, Qinci Wu, Junchuan Tang, Yisen Cao, Congwei Tan, Jilin Tang, Mengjian Zhu, Yani Wang, Yanglizhi Li, Luzhao Sun, Guanghui Gao, Jianbo Yin, Li Lin, Zhongfan Liu, Shiqiao Qin, and Hailin Peng

Subjects
Science
Abstract

Defect-free integration of 2D materials onto semiconductor wafers is desired to implement heterogeneous electronic devices. Here, the authors report a method to transfer high-quality graphene on target wafers via gradient surface energy modulation, leading to improved structural and electronic properties.

Published
2022
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2. Photodegradation and van der Waals Passivation of Violet Phosphorus

Author

Xiangzhe Zhang, Bowen Lv, Haitao Wei, Xingheng Yan, Gang Peng, and Shiqiao Qin

Subjects
violet phosphorus, photodegradation, van der Waals passivation, Chemistry, QD1-999
Abstract

Violet phosphorus (VP), a novel two-dimensional (2D) nanomaterial, boasts structural anisotropy, a tunable optical bandgap, and superior thermal stability compared with its allotropes. Its multifunctionality has sparked widespread interest in the community. Yet, the VP’s air susceptibility impedes both probing its intrinsic features and device integration, thus making it of urgent significance to unveil the degradation mechanism. Herein, we conduct a comprehensive study of photoactivated degradation effects on VP. A nitrogen annealing method is presented for the effective elimination of surface adsorbates from VP, as evidenced by a giant surface-roughness improvement from 65.639 nm to 7.09 nm, enabling direct observation of the intrinsic morphology changes induced by photodegradation. Laser illumination demonstrates a significant thickness-thinning effect on VP, manifested in the remarkable morphological changes and the 73% quenching of PL intensity within 160 s, implying its great potential for the efficient selected-area etching of VP at high resolution. Furthermore, van der Waals passivation of VP using 2D hexagonal boron nitride (hBN) was achieved. The hBN-passivated channel exhibited improved surface roughness (0.512 nm), reduced photocurrent hysteresis, and lower responsivity (0.11 A/W @ 450 nm; 2 μW), effectively excluding adsorbate-induced electrical and optoelectrical effects while disabling photodegradation. Based on our experimental results, we conclude that three possible factors contribute to the photodegradation of VP: illumination with photon energy higher than the bandgap, adsorbed H2O, and adsorbed O2.

Published
2024
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4. Effect of induced current loss on quality factor of graphene resonators

Author

Yang Xiao, Feng Hu, Mengjian Zhu, Jiaxing Zheng, Xuefeng Song, Ying Liu, and Shiqiao Qin

Subjects
Physics, QC1-999
Abstract

As the important electric loss of a graphene resonator, intrinsic current loss has received increasing attention, but the existing research is limited to qualitative analysis and approximate calculation. Based on the microscopic behavior of carriers, we have accurately established the calculation model of induced current loss, which is in good agreement with the existing experimental results. Compared with the previous models, the model in this work can not only fit the inverse V-shaped Q − Vdc curve well but also be compatible with the V-shaped Q − Vdc curve, which is beyond the reach of the previous models. In addition, the calculation results show that selecting the appropriate gate voltage combination when stimulating the graphene resonator can increase the quality factor by nearly 1–2 orders of magnitude. Furthermore, we reasonably explain the importance of DC gate voltage applied in the experiment compared with the case of non-DC gate voltage. This work realizes the accurate calculation of intrinsic current loss and is of great significance for reducing the intrinsic current loss in the practical application of graphene resonators.

Published
2022
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5. Electrically-driven ultrafast out-of-equilibrium light emission from hot electrons in suspended graphene/hBN heterostructures

Author

Qiang Liu, Wei Xu, Xiaoxi Li, Tongyao Zhang, Chengbing Qin, Fang Luo, Zhihong Zhu, Shiqiao Qin, Mengjian Zhu, and Kostya S Novoselov

Subjects
suspended graphene, ultrafast light emitter, van der Waals heterostructures, thermal radiation, electron–phonon interaction, Materials of engineering and construction. Mechanics of materials, TA401-492, Industrial engineering. Management engineering, T55.4-60.8, Physics, QC1-999
Abstract

Nanoscale light sources with high speed of electrical modulation and low energy consumption are key components for nanophotonics and optoelectronics. The record-high carrier mobility and ultrafast carrier dynamics of graphene make it promising as an atomically thin light emitter, which can be further integrated into arbitrary platforms by van der Waals forces. However, due to the zero bandgap, graphene is difficult to emit light through the interband recombination of carriers like conventional semiconductors. Here, we demonstrate ultrafast thermal light emitters based on suspended graphene/hexagonal boron nitride (Gr/hBN) heterostructures. Electrons in biased graphene are significantly heated up to 2800 K at modest electric fields, emitting bright photons from the near-infrared to the visible spectral range. By eliminating the heat dissipation channel of the substrate, the radiation efficiency of the suspended Gr/hBN device is about two orders of magnitude greater than that of graphene devices supported on SiO _2 or hBN. We further demonstrate that hot electrons and low-energy acoustic phonons in graphene are weakly coupled to each other and are not in full thermal equilibrium. Direct cooling of high-temperature hot electrons to low-temperature acoustic phonons is enabled by the significant near-field heat transfer at the highly localized Gr/hBN interface, resulting in ultrafast thermal emission with up to 1 GHz bandwidth under electrical excitation. It is found that suspending the Gr/hBN heterostructures on the SiO _2 trenches significantly modifies the light emission due to the formation of the optical cavity and showed a ∼440% enhancement in intensity at the peak wavelength of 940 nm compared to the black-body thermal radiation. The demonstration of electrically driven ultrafast light emission from suspended Gr/hBN heterostructures sheds the light on applications of graphene heterostructures in photonic integrated circuits, such as broadband light sources and ultrafast thermo-optic phase modulators.

Published
2023
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6. Near-Infrared Photoelectric Properties of Multilayer Bi2O2Se Nanofilms

Author

Hang Yang, Wei Chen, Xiaoming Zheng, Dongsheng Yang, Yuze Hu, Xiangzhe Zhang, Xin Ye, Yi Zhang, Tian Jiang, Gang Peng, Xueao Zhang, Renyan Zhang, Chuyun Deng, and Shiqiao Qin

Subjects
Bi2O2Se, Multilayer, Photodetector, Near-Infrared, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Abstract The near-infrared (NIR) photoelectric properties of multilayer Bi2O2Se nanofilms were systematically studied in this paper. Multilayer Bi2O2Se nanofilms demonstrate a sensitive photo response to NIR, including a high photoresponsivity (~ 101 A/W), a quick response time (~ 30 ms), a high external quantum efficiency (~ 20,300%), and a high detection rate (1.9 × 1010 Jones). These results show that the device based on multilayer Bi2O2Se nanofilms might have great potentials for future applications in ultrafast, highly sensitive NIR optoelectronic devices.

Published
2019
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7. Indefinite Graphene Nanocavities with Ultra-Compressed Mode Volumes

Author

Chunchao Wen, Zongyang Wang, Jipeng Xu, Wei Xu, Wei Liu, Zhihong Zhu, Jianfa Zhang, and Shiqiao Qin

Subjects
graphene indefinite cavities, anomalous scaling rules, hyperbolic medium metamaterial, mode volumes, Chemistry, QD1-999
Abstract

Explorations of indefinite nanocavities have attracted surging interest in the past few years as such cavities enable light confinement to exceptionally small dimensions, relying on the hyperbolic dispersion of their consisting medium. Here, we propose and study indefinite graphene nanocavities, which support ultra-compressed mode volumes with confinement factors up to 109. Moreover, the nanocavities we propose manifest anomalous scaling laws of resonances and can be effectively excited from the far field. The indefinite graphene cavities, based on low dimensional materials, present a novel rout to squeeze light down to the nanoscale, rendering a more versatile platform for investigations into ultra-strong light–matter interactions at mid-infrared to terahertz spectral ranges.

Published
2022
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8. Regulation of Thermal Emission Position in Biased Graphene

Author

Yansong Fan, Zhengzhuo Zhang, Zhihong Zhu, Jianfa Zhang, Wei Xu, Fan Wu, Xiaodong Yuan, Chucai Guo, and Shiqiao Qin

Subjects
graphene, thermal emission, regulation, Chemistry, QD1-999
Abstract

A very attractive advantage of graphene is that its Fermi level can be regulated by electrostatic bias doping. It is of great significance to investigate and control the spatial location of graphene emission for graphene thermal emitters, in addition to tuning the emission intensity and emission spectrum. Here, we present a detailed theoretical model to describe the graphene emission characteristics versus gate voltages. The experimentally observed movement of the emission spot and temperature distribution of graphene emitters are basically in agreement with those from the theoretical model. Our results provide a simple method to predict the behavior of graphene emitters that is beneficial for achieving the spatial dynamic regulation of graphene infrared emission arrays.

Published
2022
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9. Far‐Field Excitation of Acoustic Graphene Plasmons with a Metamaterial Absorber

Author

Chunchao Wen, Xingqiao Chen, Jianfa Zhang, Wei Xu, Jie Luo, Yingqiu Zhou, Zhihong Zhu, Shiqiao Qin, and Xiaodong Yuan

Subjects
acoustics, graphene plasmons, metamaterials, midinfrared range, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

When a graphene sheet is placed near a metal surface, it supports a special type of highly confined and low‐loss electromagnetic mode called acoustic graphene plasmons (AGPs). AGPs squeeze infrared photons into extremely confined areas down to a subnanometric scale and provides a unique platform for strong light–matter interactions. However, the efficient excitation of AGPs is a challenge due to the large momentum mismatch between free‐space light and AGPs. With theoretical analysis and numerical simulations, it is shown that the far‐field excitation of AGPs is realized by integrating graphene in a metal–insulator–metal (MIM) metamaterial with magnetic resonance (MR). More than ten graphene plasmonic modes are excited in the midinfrared range, resulting in a multiresonant spectra with Fano‐like characteristics at each resonant wavelength. The proposal opens a new door to explore the strong plasmonic coupling between graphene and metallic metamaterials down to atomic scale for extreme nanophotonics. The potential applications range from ultracompact tunable metamaterials and ultrasensitive infrared spectroscopy to single‐molecule optics, quantum plasmonics, and others.

Published
2021
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10. Controlling Tunneling Characteristics via Bias Voltage in Bilayer Graphene/WS2/Metal Heterojunctions

Author

Zongqi Bai, Sen Zhang, Yang Xiao, Miaomiao Li, Fang Luo, Jie Li, Shiqiao Qin, and Gang Peng

Subjects
field-effect tunneling transistors, graphene-based heterojunctions, FN tunneling, energy band diagrams, Chemistry, QD1-999
Abstract

Van der Waals heterojunctions, formed by stacking two-dimensional materials with various structural and electronic properties, opens a new way to design new functional devices for future applications and provides an ideal research platform for exploring novel physical phenomena. In this work, bilayer graphene/WS2/metal heterojunctions (GWMHs) with vertical architecture were designed and fabricated. The tunneling current–bias voltage (It − Vb) properties of GWMHs can be tuned by 5 × 106 times in magnitude for current increasing from 0.2 nA to 1 mA with applied bias voltage increasing from 10 mV to 2 V. Moreover, the transfer properties of GWMHs exhibit n-type conduction at Vb = 0.1 V and bipolar conduction at Vb = 2 V; these findings are explained well by direct tunneling (DT) and Fowler–Nordheim tunneling (FNT), respectively. The results show the great potential of GWMHs for high-power field-effect transistors (FETs) and next-generation logic electronic devices.

Published
2022
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11. Selective etching in graphene–MoS2 heterostructures for fabricating graphene-contacted MoS2 transistors

Author

Zeliang Sun, Gang Peng, Zongqi Bai, Xiangzhe Zhang, Yuehua Wei, Chuyun Deng, Yi Zhang, Mengjian Zhu, Shiqiao Qin, Zheng Li, and Wei Luo

Subjects
Physics, QC1-999
Abstract

Semiconducting molybdenum disulfide (MoS2) has drawn a lot of attention for its exceptional electronic and optoelectronic properties. Despite the potential advantages, the large contact resistance at the metal–MoS2 interfaces has been one of the biggest obstacles for the realization of ideal MoS2 transistors. One solution to improve the metal–MoS2 interfaces is to use the graphene electrodes. Here, we provide a selective etching method for fabricating graphene-contacted MoS2 transistors. It has been proved that the graphene could be totally etched with Ar+ plasma treatment, and the multilayer MoS2 flake can also be reduced layer by layer with Ar+ plasma treatment. By etching graphene selectively in graphene–MoS2 heterostructures, one can obtain graphene-contacted MoS2 transistors successfully. The transistor reported in this paper shows an on–off ratio about 106 and a carrier mobility about 42 cm2 V−1 s−1. This selective etching method would be beneficial for some other graphene-contacted electronic devices.

Published
2020
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12. A Review on Graphene-Based Nano-Electromechanical Resonators: Fabrication, Performance, and Applications

Author

Yang Xiao, Fang Luo, Yuchen Zhang, Feng Hu, Mengjian Zhu, and Shiqiao Qin

Subjects
graphene, nano-resonator, resonance frequency, sensing, Mechanical engineering and machinery, TJ1-1570
Abstract

The emergence of graphene and other two-dimensional materials overcomes the limitation in the characteristic size of silicon-based micro-resonators and paved the way in the realization of nano-mechanical resonators. In this paper, we review the progress to date of the research on the fabrication methods, resonant performance, and device applications of graphene-based nano-mechanical resonators, from theoretical simulation to experimental results, and summarize both the excitation and detection schemes of graphene resonators. In recent years, the applications of graphene resonators such as mass sensors, pressure sensors, and accelerometers gradually moved from theory to experiment, which are specially introduced in this review. To date, the resonance performance of graphene-based nano-mechanical resonators is widely studied by theoretical approaches, while the corresponding experiments are still in the preliminary stage. However, with the continuous progress of the device fabrication and detection technique, and with the improvement of the theoretical model, suspended graphene membranes will widen the potential for ultralow-loss and high-sensitivity mechanical resonators in the near future.

Published
2022
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13. A Novel Two-Axis Differential Resonant Accelerometer Based on Graphene with Transmission Beams

Author

Yang Xiao, Feng Hu, Yuchen Zhang, Jiaxing Zheng, and Shiqiao Qin

Subjects
graphene resonant, biaxial accelerometer, finite element simulation, differential mode, Chemical technology, TP1-1185
Abstract

In this paper, a novel two-axis differential resonant accelerometer based on graphene with transmission beams is presented. This accelerometer can not only reduce the cross sensitivity, but also overcome the influence of gravity, realizing fast and accurate measurement of the direction and magnitude of acceleration on the horizontal plane. The simulation results show that the critical buckling acceleration is 460 g, the linear range is 0–89 g, while the differential sensitivity is 50,919 Hz/g, which is generally higher than that of the resonant accelerometer reported previously. Thus, the accelerometer belongs to the ultra-high sensitivity accelerometer. In addition, increasing the length and tension of graphene can obviously increase the critical linear acceleration and critical buckling acceleration with the decreasing sensitivity of the accelerometer. Additionally, the size change of the force transfer structure can significantly affect the detection performance. As the etching accuracy reaches the order of 100 nm, the critical buckling acceleration can reach up to 5 × 104 g, with a sensitivity of 250 Hz/g. To sum up, a feasible design of a biaxial graphene resonant accelerometer is proposed in this work, which provides a theoretical reference for the fabrication of a graphene accelerometer with high precision and stability.

Published
2022
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14. Stress Effects on Temperature-Dependent In-Plane Raman Modes of Supported Monolayer Graphene Induced by Thermal Annealing

Author

Yuehua Wei, Zhenhua Wei, Xiaoming Zheng, Jinxin Liu, Yangbo Chen, Yue Su, Wei Luo, Gang Peng, Han Huang, Weiwei Cai, Chuyun Deng, Xueao Zhang, and Shiqiao Qin

Subjects
monolayer graphene, temperature-dependent in-plane Raman phonon modes, temperature coefficient, thermal annealing, compressive stress, Chemistry, QD1-999
Abstract

The coupling strength between two-dimensional (2D) materials and substrate plays a vital role on thermal transport properties of 2D materials. Here we systematically investigate the influence of vacuum thermal annealing on the temperature-dependence of in-plane Raman phonon modes in monolayer graphene supported on silicon dioxide substrate via Raman spectroscopy. Intriguingly, raising the thermal annealing temperature can significantly enlarge the temperature coefficient of supported monolayer graphene. The derived temperature coefficient of G band remains mostly unchanged with thermal annealing temperature below 473 K, while it increases from −0.030 cm−1/K to −0.0602 cm−1/K with thermal annealing temperature ranging from 473 K to 773 K, suggesting the great impact of thermal annealing on thermal transport in supported monolayer graphene. Such an impact might reveal the vital role of coupling strength on phonon scattering and on the thermal transport property of supported monolayer graphene. To further interpret the thermal annealing mechanism, the compressive stress in supported monolayer graphene, which is closely related to coupling strength and is studied through the temperature-dependent Raman spectra. It is found that the variation tendency for compressive stress induced by thermal annealing is the same as that for temperature coefficient, implying the intense connection between compressive stress and thermal transport. Actually, 773 K thermal annealing can result in 2.02 GPa compressive stress on supported monolayer graphene due to the lattice mismatch of graphene and substrate. This study proposes thermal annealing as a feasible path to modulate the thermal transport in supported graphene and to design future graphene-based devices.

Published
2021
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15. Enhanced Molecular Infrared Spectroscopy Employing Bilayer Graphene Acoustic Plasmon Resonator

Author

Chunchao Wen, Jie Luo, Wei Xu, Zhihong Zhu, Shiqiao Qin, and Jianfa Zhang

Subjects
acoustic graphene plasmons, bilayer graphene, infrared spectroscopy, molecular vibrational fingerprints, Biotechnology, TP248.13-248.65
Abstract

Graphene plasmon resonators with the ability to support plasmonic resonances in the infrared region make them a promising platform for plasmon-enhanced spectroscopy techniques. Here we propose a resonant graphene plasmonic system for infrared spectroscopy sensing that consists of continuous graphene and graphene ribbons separated by a nanometric gap. Such a bilayer graphene resonator can support acoustic graphene plasmons (AGPs) that provide ultraconfined electromagnetic fields and strong field enhancement inside the nano-gap. This allows us to selectively enhance the infrared absorption of protein molecules and precisely resolve the molecular structural information by sweeping graphene Fermi energy. Compared to the conventional graphene plasmonic sensors, the proposed bilayer AGP sensor provides better sensitivity and improvement of molecular vibrational fingerprints of nanoscale analyte samples. Our work provides a novel avenue for enhanced infrared spectroscopy sensing with ultrasmall volumes of molecules.

Published
2021
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16. High Q Resonant Graphene Absorber with Lossless Phase Change Material Sb2S3

Author

Qi Meng, Xingqiao Chen, Wei Xu, Zhihong Zhu, Shiqiao Qin, Jianfa Zhang, and Xiaodong Yuan

Subjects
graphene absorbers, phase change material, high Q, Chemistry, QD1-999
Abstract

Graphene absorbers have attracted lots of interest in recent years. They provide huge potential for applications such as photodetectors, modulators, and thermal emitters. In this letter, we design a high-quality (Q) factor resonant graphene absorber based on the phase change material Sb2S3. In the proposed structure, a refractive index grating is formed at the subwavelength scale due to the periodical distributions of amorphous and crystalline states, and the structure is intrinsically flat. The numerical simulation shows that nearly 100% absorption can be achieved at the wavelength of 1550 nm, and the Q factor is more than hundreds due to the loss-less value of Sb2S3 in the near-infrared region. The absorption spectra can be engineered by changing the crystallization fraction of the Sb2S3 as well as by varying the duty cycle of the grating, which can be employed not only to switch the resonant wavelength but also to achieve resonances with higher Q factors. This provides a promising method for realizing integrated graphene optoelectronic devices with the desired functionalities.

Published
2021
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17. Fano-Resonance in Hybrid Metal-Graphene Metamaterial and Its Application as Mid-Infrared Plasmonic Sensor

Author

Jianfa Zhang, Qilin Hong, Jinglan Zou, Yuwen He, Xiaodong Yuan, Zhihong Zhu, and Shiqiao Qin

Subjects
fano resonance, graphene, plasmonic sensor, Mechanical engineering and machinery, TJ1-1570
Abstract

Fano resonances in nanostructures have attracted widespread research interests in the past few years for their potential applications in sensing, switching and nonlinear optics. In this paper, a mid-infrared Fano resonance in a hybrid metal-graphene metamaterial is studied. The hybrid metamaterial consists of a metallic grid enclosing with graphene nanodisks. The Fano resonance arises from the coupling of graphene and metallic plasmonic resonances and it is sharper than plasmonic resonances in pure graphene nanostructures. The resonance strength can be enhanced by increasing the number of graphene layers. The proposed metamaterial can be employed as a high-performance mid-infrared plasmonic sensor with an unprecedented sensitivity of about 7.93 μ m/RIU and figure of merit (FOM) of about 158 . 7 .

Published
2020
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18. Influence of Temperature Variation on the Vibrational Characteristics of Fused Silica Cylindrical Resonators for Coriolis Vibratory Gyroscopes

Author

Pengbo Xiao, Zhinan Qiu, Yiming Luo, Yao Pan, Tianliang Qu, Kaiyong Yang, Hui Luo, and Shiqiao Qin

Subjects
fused silica cylindrical resonator, frequency mismatch, q factor, temperature, coriolis vibratory gyroscope, Chemical technology, TP1-1185
Abstract

The fused silica cylindrical resonator is a type of axisymmetric resonator that can be used for Coriolis vibratory gyroscopes. Although the resonant frequency, frequency mismatch, and Q factor are natural properties of the resonator, they can change with temperature. Therefore, the temperature drift severely limits the detection accuracy and bias stability of the gyroscope. In this paper, the influence of temperature variation on the vibrational characteristics of fused silica cylindrical resonators was investigated. Experiments were performed on a fused silica cylindrical resonator coated with Cr/Au films. It was shown that at the temperature range from 253.15 K to 353.15 K, the resonant frequency linearly increased with temperature, the frequency mismatch remained unchanged, and the Q factor gradually increased till about 333.15 K, when it began to decrease. Meanwhile, the change of thermoelastic damping with temperature may dominate the variation of Q factor at the temperature range from 253.15 K to 353.15 K. This phenomenon was theoretically analyzed and the variation trends of results were consistent with the theoretical analysis. This study indicates that, for the fused silica cylindrical resonator, to discover the influence of temperature variation on the resonant frequency, frequency mismatch, and Q factor, there are certain rules to follow and repeat. The relationship between temperature and frequency can be established, which provides the feasibility of using self-calibration based on temperature characteristics of the resonator for temperature drift compensations. Additionally, there is an optimum temperature that may improve the performance of the Coriolis vibratory gyroscope with the fused silica cylindrical resonator.

Published
2020
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19. Influence of Electrostatic Forces on the Vibrational Characteristics of Resonators for Coriolis Vibratory Gyroscopes

Author

Pengbo Xiao, Zhinan Qiu, Yao Pan, Shaoliang Li, Tianliang Qu, Zhongqi Tan, Jianping Liu, Kaiyong Yang, Wanliang Zhao, Hui Luo, and Shiqiao Qin

Subjects
coriolis vibratory gyroscope, fused silica cylindrical resonator, frequency mismatch, q factor, electrostatic forces, Chemical technology, TP1-1185
Abstract

The Coriolis Vibratory Gyroscopes are a type of sensors that measure angular velocities through the Coriolis effect. The resonator is the critical component of the CVGs, the vibrational characteristics of which, including the resonant frequency, frequency mismatch, Q factor, and Q factor asymmetry, have a great influence on the performance of CVG. The frequency mismatch and Q factor of the resonator, in particular, directly determine the precision and drift characteristics of the gyroscope. Although the frequency mismatch and Q factor are natural properties of the resonator, they can change with external conditions, such as temperature, pressure, and external forces. In this paper, the influence of electrostatic forces on the vibrational characteristics of the fused silica cylindrical resonator is investigated. Experiments were performed on a fused silica cylindrical resonator coated with Cr/Au films. It was shown that the resonant frequency, frequency mismatch, and the decay time slightly decreased with electrostatic forces, while the decay time split increased. Lower capacitive gaps and larger applied voltages resulted in lower frequency mismatch and lower decay time. This phenomenon was theoretically analyzed, and the variation trends of results were consistent with the theoretical analysis. This study indicates that, for fused silica cylindrical resonator with electrostatic transduction, the electrostatic influence on the Q factor and frequency, although small, should be considered when designing the capacitive gap and choosing bias voltages.

Published
2020
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20. High responsivity graphene photodetectors from visible to near-infrared by photogating effect

Author

Fang Luo, Mengjian Zhu, Yuan tan, Honghui Sun, Wei Luo, Gang Peng, Zhihong Zhu, Xue-Ao Zhang, and Shiqiao Qin

Subjects
Physics, QC1-999
Abstract

Graphene photodetectors are highly attractive owing to its ultra-fast and wide-range spectral response from visible to infrared benefit from the superior carrier mobility and the linear dispersion with zero bandgap of graphene. The application of graphene photodetectors however is seriously limited by the low intrinsic responsivity in the order of ∼10 mA/W. Here, we demonstrate photogating field-effect transistors based on pure monolayer graphene with simple device structures. The light absorption in the heavily n-doped silicon/silicon oxide (Si/SiO2) substrate generates an additional photovoltage that effectively modulates the conductance of graphene, leading to room temperature graphene photodetectors with high responsivity of ∼500 A/W for 450 nm light and ∼4 A/W for 1064 nm light, respectively. The generated photocurrent changes with applied gate voltage and shows a strongly nonlinear power dependence. Meanwhile, the photoresponse of graphene exhibits a cut-off wavelength of ∼1100 nm, confirming the dominance photogating effect caused by light absorption in Si/SiO2 substrate. Considering the great compatibility of graphene to Si technology, our result paves a way for high-performance chip-integrated photodetectors.

Published
2018
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21. Interlayer Difference of Bilayer-Stacked MoS2 Structure: Probing by Photoluminescence and Raman Spectroscopy

Author

Xiangzhe Zhang, Renyan Zhang, Xiaoming Zheng, Yi Zhang, Xueao Zhang, Chuyun Deng, Shiqiao Qin, and Hang Yang

Subjects
film–substrate interaction, photoluminescence, Raman spectroscopy, molybdenum disulfide, bilayer-stacked structure, Chemistry, QD1-999
Abstract

This work reports the interlayer difference of exciton and phonon performance between the top and bottom layer of a bilayer-stacked two-dimensional materials structure (BSS). Through photoluminescence (PL) and Raman spectroscopy, we find that, compared to that of the bottom layer, the top layer of BSS demonstrates PL redshift, Raman E 2 g 1 mode redshift, and lower PL intensity. Spatial inhomogeneity of PL and Raman are also observed in the BSS. Based on theoretical analysis, these exotic effects can be attributed to substrate-coupling-induced strain and doping. Our findings provide pertinent insight into film−substrate interaction, and are of great significance to researches on bilayer-stacked structures including twisted bilayer structure, Van der Waals hetero- and homo-structure.

Published
2019
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22. Graphene-Based Perfect Absorption Structures in the Visible to Terahertz Band and Their Optoelectronics Applications

Author

Chucai Guo, Jianfa Zhang, Wei Xu, Ken Liu, Xiaodong Yuan, Shiqiao Qin, and Zhihong Zhu

Subjects
graphene, perfect absorption, optoelectronic devices, Chemistry, QD1-999
Abstract

Graphene has unique properties which make it an ideal material for photonic and optoelectronic devices. However, the low light absorption in monolayer graphene seriously limits its practical applications. In order to greatly enhance the light absorption of graphene, many graphene-based structures have been developed to achieve perfect absorption of incident waves. In this review, we discuss and analyze various types of graphene-based perfect absorption structures in the visible to terahertz band. In particular, we review recent advances and optoelectronic applications of such structures. Indeed, the graphene-based perfect absorption structures offer the promise of solving the key problem which limits the applications of graphene in practical optoelectronic devices.

Published
2018
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23. A Comprehensive Calibration Method for a Star Tracker and Gyroscope Units Integrated System

Author

Wenfeng Tan, Dongkai Dai, Wei Wu, Xingshu Wang, and Shiqiao Qin

Subjects
star tracker, gyroscope units, comprehensive calibration, Kalman filter, Chemical technology, TP1-1185
Abstract

The integration of a star tracker and gyroscope units (GUs) can take full advantage of the benefits of each, and provide continuous and accurate attitude information with a high update rate. The systematic error calibration of the integrated system is a crucial step to guarantee its attitude accuracy. In this paper, a comprehensive calibration method for the star tracker and GUs integrated system is proposed from a global perspective. Firstly, the observation model of the predicted star centroid error (PSCE) with respect to the systematic errors including the star tracker intrinsic parameter errors, GUs errors and fixed angle errors is accurately established. Then, the systematic errors are modeled by a series of differential equations, based on which the state-space model is established. Finally, the systematic errors are decoupled and estimated by a Kalman filter according to the established state-space model and observation model. The coupling between the errors of the principal point and subcomponents of the fixed angles (i.e., Ψ x and Ψ y ) is analysed. Both simulations and experiments indicate that the proposed method is effective at estimating the systematic errors of the star tracker and GUs integrated system with high accuracy and robustness with respect to different star centroid accuracies and gyroscope noise levels.

Published
2018
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24. A New Bias Error Prediction Model for High-Precision Transfer Alignment

Author

Yutong Zhang, Shuai Yang, Shiqiao Qin, Feng Hu, and Wei Wu

Subjects
inertial navigation systems (INS), transfer alignment, dynamic lever-arm, ship prediction linear motion, bias error, Chemical technology, TP1-1185
Abstract

The purpose of this work was to study bias error in acceleration-based transfer alignment, which is probably caused by cross-correlation between the dynamic lever-arm and the linear motion of a ship. A new prediction model for the cross-correlation-caused error is proposed in this paper. We adopt the Bernoulli-Euler Beam as a simplified ship hull-girder model to verify the existence of the cross-correlation. Then, the mathematical mechanism and the prediction model of the bias error are deduced via the ordinary least squares theory. Three factors influence the bias error in the prediction model: the amplitude of the dynamic lever arm acceleration, the amplitude of the ship motion acceleration, and the cross-correlation between them. Simulation experiments are then conducted to test the influence of the factors. The results show that the mechanism analysis is reasonable, and the bias error prediction model is in agreement with the experimental results. Thus, the proposed prediction model has the potential to deduce the bias error in high-accuracy transfer alignment.

Published
2018
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25. The Raman redshift of graphene impacted by gold nanoparticles

Author

Xiaoming Zheng, Wei Chen, Guang Wang, Yayun Yu, Shiqiao Qin, Jingyue Fang, Fei Wang, and Xue-Ao Zhang

Subjects
Physics, QC1-999
Abstract

The influence of gold nanoparticles (GNPs) on graphene was studied by Raman spectroscopy. It was found that the contact of GNPs could induce the whole Raman spectrum of graphene to redshift. And the shift of the 2D peak is more obvious than that of the G peak. A model of local strain was brought forward to explain the shift of Raman spectrum, which comes from the charges transfer between the GNPs and graphene. The observation of the Raman shifts helps us to gain more physical insights into the graphene-related systems.

Published
2015
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26. An Al2O3 Gating Substrate for the Greater Performance of Field Effect Transistors Based on Two-Dimensional Materials

Author

Hang Yang, Shiqiao Qin, Xiaoming Zheng, Guang Wang, Yuan Tan, Gang Peng, and Xueao Zhang

Subjects
graphene, WS2, Al2O3 gating substrate, field effect transistors, Chemistry, QD1-999
Abstract

We fabricated 70 nm Al2O3 gated field effect transistors based on two-dimensional (2D) materials and characterized their optical and electrical properties. Studies show that the optical contrast of monolayer graphene on an Al2O3/Si substrate is superior to that on a traditional 300 nm SiO2/Si substrate (2.4 times). Significantly, the transconductance of monolayer graphene transistors on the Al2O3/Si substrate shows an approximately 10-fold increase, due to a smaller dielectric thickness and a higher dielectric constant. Furthermore, this substrate is also suitable for other 2D materials, such as WS2, and can enhance the transconductance remarkably by 61.3 times. These results demonstrate a new and ideal substrate for the fabrication of 2D materials-based electronic logic devices.

Published
2017
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27. Electrically Tunable Absorption Enhancement with Spectral and Polarization Selectivity through Graphene Plasmonic Light Trapping

Author

Wenbin Liu, Jianfa Zhang, Zhihong Zhu, Xiaodong Yuan, and Shiqiao Qin

Subjects
graphene, plasmonic, absorption enhancement, polarization selectivity, photodetectors, Chemistry, QD1-999
Abstract

In this paper, anisotropic graphene plasmonic structures are explored for light trapping and absorption enhancement in surrounding media. It is shown that electrically tunable and versatile spectral and polarization selectivity can be realized. Particularly, it is possible to control absorption of the incident light’s polarization component at a specific wavelength by varying the Fermi energy with suitable geometric designs. It may find applications for new types of infrared and THz photodetectors and will promote the research of other novel polarization devices.

Published
2016
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28. The nonlinear optical properties of coupling and decoupling graphene layers

Author

Wei Chen, Guang Wang, Shiqiao Qin, Chaocheng Wang, Jingyue Fang, Junli Qi, Xueao Zhang, Li Wang, Honghui Jia, and Shengli Chang

Subjects
Physics, QC1-999
Abstract

Third-order optical nonlinearities of graphene from monolayer to multilayers were investigated in the femtosecond regime, and the contribution of interlayer coupling to the nonlinearities was studied. The nonlinear refractive index γ of the order of 10−9 cm2/W and the nonlinear absorption coefficient β of 10−6 cm/W were obtained. By systematically investigating the nonlinear optical properties with the number of layers and comparing the coupling graphene with the decoupling superimposed graphene, we found that the coupling of interlayers has large effect upon the nonlinear refraction. These results provide an effective approach for developing graphene-based nonlinear photonic devices.

Published
2013
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35. Electrically Controlled Wavelength-Tunable Photoluminescence from van der Waals Heterostructures

Author

Hongwu Tang, Fang Luo, Ziru Cui, Yang Xiao, Wei Xu, Zhihong Zhu, Shula Chen, Xiao Wang, Yanping Liu, Jinbin Wang, Gang Peng, Shiqiao Qin, and Mengjian Zhu

Subjects
General Materials Science
Abstract

Achieving facile control of the wavelength of light emitters is of great significance for many key applications in optoelectronics and photonics, including on-chip interconnection, super-resolution imaging, and optical communication. The Joule heating effect caused by electric current is widely applied in modulating the refractive index of silicon-based waveguides for reconfigurable nanophotonic circuits. Here, by utilizing localized Joule heating in the biased graphene device, we demonstrate electrically controlled wavelength-tunable photoluminescence (PL) from vertical van der Waals heterostructures combined by graphene and two-dimensional transition metal dichalcogenides (2D-TMDCs). By applying a moderate electric field of 6.5 kV·cm

Published
2022

38. High Mobility Two-Dimensional Bismuth Oxyselenide Single Crystals with Large Grain Size Grown by Reverse-Flow Chemical Vapor Deposition

Author

Yansong Fan, Zhihong Zhu, Yuwen He, Zongqi Bai, Guang Wang, Kostya S. Novoselov, Mengjian Zhu, Xi Yang, Yingchao Song, Shiqiao Qin, Gang Peng, Qi Zhang, and Qing Luo

Subjects
Electron mobility, Materials science, business.industry, Nucleation, chemistry.chemical_element, Chemical vapor deposition, Grain size, Bismuth, Semiconductor, Nanoelectronics, chemistry, Optoelectronics, General Materials Science, Field-effect transistor, business
Abstract

2D semiconductors with atomically thin body thickness have attracted tremendous research interest for high-performance nanoelectronics and optoelectronics. Most of the 2D semiconductors grown by chemical vapor deposition (CVD) methods suffer from rather low carrier mobility, small single-crystal size, and instability under ambient conditions. Here, we develop an improved CVD method with controllable reverse-gas flow to realize the direct growth of quality Bi2O2Se 2D single crystals on a mica substrate. The applied reverse flow significantly suppresses the random nucleation and thus promotes the lateral size of 2D Bi2O2Se crystals up to ∼750 μm. The Bi2O2Se field-effect transistors display high-room-temperature electron mobility up to ∼1400 cm2·V-1·s-1 and a well-defined drain current saturation. The on/off ratio of the Bi2O2Se transistor is larger than 107, and the sub-threshold swing is about 90 mV·dec-1. The responsivity, response time, and detectivity of Bi2O2Se photodetectors approach up to 60 A·W-1, 5 ms, and 2.4 × 1010 Jones at room temperature, respectively. Our results demonstrate large-size and high-quality Bi2O2Se grown by reverse-flow CVD as a high-performance channel material for next-generation transistors and photodetectors.

Published
2021

39. Strain-Induced Alternating Photoluminescence Segmentation in Hexagonal Monolayer Tungsten Disulfide Grown by Physical Vapor Deposition

Author

Zhihong Zhu, Xi Yang, Mengjian Zhu, Fang Luo, Shiqiao Qin, Guang Wang, and Gang Peng

Subjects
Kelvin probe force microscope, Condensed Matter::Materials Science, Strain engineering, Photoluminescence, Materials science, genetic structures, Band gap, Exciton, Microscopy, Monolayer, General Materials Science, Light emission, Molecular physics
Abstract

Two-dimensional semiconductors exhibit strong light emission under optical or electrical pumping due to quantum confinement and large exciton binding energies. The regulation of the light emission shows great application potential in next-generation optoelectronic devices. Herein, by the physical vapor deposition strategy, we synthesize monolayer hexagonal-shaped WS2, and its photoluminescence intensity mapping show three-fold symmetric patterns with alternating bright and dark regions. Regardless of the length of the edges, all domains with S-terminated edges show lower photoluminescence intensity, while all regions with W-terminated edges exhibit higher photoluminescence intensity. The photoluminescence segmentation mechanism is studied in detail by employing Raman spectroscopy, atomic force microscopy, high-resolution transmission electron microscopy, and Kelvin probe force microscopy, and it is found to originate from different strain distributions in the S-terminated region and the W-terminated region. The optical band gap determined by the photoluminescence in the dark region is ∼2 meV lower than that in the bright region, implying that more strain is stored in the S-terminated region than in the W-terminated region. The photoluminescence segmentation vanishes in transferred hexagonal-shaped WS2 from the initial substrate to a fresh silicon substrate, further confirming the physical mechanism. Our results provide guidance for tuning the optical properties of two-dimensional semiconductors by controllable strain engineering.

Published
2021

40. Visible light emission enhancement from a graphene-based metal Fabry-Pérot cavity

Author

Yansong Fan, Zhihong Zhu, Janfa Zhang, Wei Xu, Fan Wu, Xiaodong Yuan, Chucai Guo, and Shiqiao Qin

Subjects
Atomic and Molecular Physics, and Optics
Abstract

The high saturation current density and ultrafast heating modulation of graphene makes it a competitive candidate for future thermal emission source. However, the low emissivity and easy oxidation under high temperature in air limit graphene application in the spectral range from the visible to near infrared. Here, we report a visible graphene thermal emitter based on the metal Fabry-Pérot (FP) cavity, which can greatly enhance the emissivity of graphene at wavelength around 637 nm and protect graphene from oxidation. We investigate the temperature characteristics of the emitter, and find the temperature of hot electrons in graphene is much higher than that of graphene lattice. Moreover, we also demonstrate the wavelength and intensity of graphene emission could be controlled by tuning the dielectric thickness between two gold layers. These results are helpful in the development of advanced graphene electro-thermal emission controlling application.

Published
2022

41. Adaptive section non-uniformity correction method of short-wave infrared star images for a star tracker

Author

Yuanman Ni, Xingshu Wang, Dongkai Dai, Wenfeng Tan, and Shiqiao Qin

Subjects
Electrical and Electronic Engineering, Engineering (miscellaneous), Atomic and Molecular Physics, and Optics
Abstract

Using a short-wave infrared (SWIR) camera to improve daytime star detection ability has become a trend for near-ground star trackers. However, the noise of SWIR star images greatly decreases the accuracy of the attitude measurement results. Aiming at a real-time application of the star tracker, an adaptive section non-uniformity correction method based on the two-point correction algorithm for SWIR star images is proposed. The correction parameters of different sections are first calculated after the defective pixels are detected and excluded, and the real-time image is corrected using adaptive section parameters according to its gray value distribution. Finally, the defective pixels are compensated for by their adjacent corrected pixels. The correction results of both simulated and live-shot star images have verified the validity of the proposed method. It adapts to different sky background radiation, which is effective for the application of a star tracker. By comparing with other linear correction methods, it has the advantages of low calculation complexity, better real-time performance, and easier implementation in the hardware.

Published
2022

42. Anisotropic in-plane thermal conductivity for multi-layer WTe2

Author

Wei Luo, Yi Zhang, Jinxin Liu, Gang Peng, Xiaoming Zheng, Chuyun Deng, Yangbo Chen, Qi Ge, Weiwei Cai, Xueao Zhang, Han Huang, Xiangzhe Zhang, Shiqiao Qin, Yuehua Wei, and Renyan Zhang

Subjects
Materials science, business.industry, 02 engineering and technology, Substrate (electronics), 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, symbols.namesake, Thermal conductivity, Nanoelectronics, Zigzag, Waste heat, Thermal, symbols, Optoelectronics, General Materials Science, Electrical and Electronic Engineering, 0210 nano-technology, Anisotropy, business, Debye model
Abstract

Improving thermal transport between substrate and transistors has become a vital solution to the thermal challenge in nanoelectronics. Recently 2D WTe2 has sparked extensive interest because of heavy atomic mass and low Debye temperature. Here, the thermal transport of supported WTe2 was studied via Raman thermometry with electrical heating. The supported 30 nm WTe2 encased with 70 nm Al2O3 delivered 4.8 W·m−1·K−1 in-plane thermal conductivity along zigzag direction at room temperature, which was almost 1.6 times larger than that along armchair direction (3.0 W·m−1·K−1). Interestingly, the superior and inferior directions for thermal transport are just opposite of those for electrical transport. Hence, a heat manipulation model in WTe2 FET device was proposed. Within the designed configuration, waste heat in WTe2 would be mostly dissipated to metal contacts located along zigzag, relieving the local temperature discrepancy in the channel effectively and preventing degradation or breakdown. Our study provides new insight into thermal transport of anisotropic 2D materials, which might inspire energy-efficient nanodevices in the future.

Published
2021

43. Optical nonlinearity and non-reciprocal transmission of graphene integrated metasurface

Author

Jianfa Zhang, Shiqiao Qin, Zhihong Zhu, Ken Liu, Xingqiao Chen, Xiaodong Yuan, and Chunchao Wen

Subjects
Kerr effect, Materials science, Optical isolator, business.industry, Graphene, Physics::Optics, 02 engineering and technology, General Chemistry, Grating, 010402 general chemistry, 021001 nanoscience & nanotechnology, Polarization (waves), 01 natural sciences, 0104 chemical sciences, law.invention, Nonlinear system, law, Transmittance, Optoelectronics, General Materials Science, Photonics, 0210 nano-technology, business
Abstract

Non-reciprocal phenomena generated by optical nonlinear effects without the requirement of external bias have important applications in modern photonics. In this paper, an optical nonlinear metasurface based on monolayer graphene integrated silicon resonant gratings is proposed. It is numerically confirmed that this type of metasurface can excite high-Q guided mode resonances in the communication band with normal incidence. Significant optical Kerr effect is achieved in the metasurface through high third-order polarization coefficient of graphene, and by changing the width and depth of the grating, the nonlinear effect of the metasurface can be effectively controlled to realize the application under different illumination conditions. In addition, remarkable non-reciprocity phenomenon is realized at an incident intensity of 0.085 G W / m 2 . As an example, with a forward transmittance of 0.732 and a backward transmittance of 0.025, an optical diode is implemented at 1549.1 n m .

Published
2021

45. Light-induced irreversible structural phase transition in trilayer graphene

Author

Xiaoming Yuan, Shiqiao Qin, Xi Yang, Weiqi Cao, Jinsen Han, Jianyu Zhang, Zheng Han, Jianing Chen, Wei Xu, Gang Peng, Mengjian Zhu, Jiayu Dai, Zhihong Zhu, Yongjun Li, Kostya S. Novoselov, and Ken Liu

Subjects
lcsh:Applied optics. Photonics, Materials science, Stacking, 02 engineering and technology, engineering.material, 01 natural sciences, Article, law.invention, symbols.namesake, Hall effect, law, Phase (matter), 0103 physical sciences, lcsh:QC350-467, Graphite, 010306 general physics, Quantum, Condensed matter physics, Graphene, Diamond, lcsh:TA1501-1820, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Optical properties and devices, Raman spectroscopy, engineering, symbols, 0210 nano-technology, lcsh:Optics. Light
Abstract

A crystal structure has a profound influence on the physical properties of the corresponding material. By synthesizing crystals with particular symmetries, one can strongly tune their properties, even for the same chemical configuration (compare graphite and diamond, for instance). Even more interesting opportunities arise when the structural phases of crystals can be changed dynamically through external stimulations. Such abilities, though rare, lead to a number of exciting phenomena, such as phase-change memory effects. In the case of trilayer graphene, there are two common stacking configurations (ABA and ABC) that have distinct electronic band structures and exhibit very different behaviors. Domain walls exist in the trilayer graphene with both stacking orders, showing fascinating new physics such as the quantum valley Hall effect. Extensive efforts have been dedicated to the phase engineering of trilayer graphene. However, the manipulation of domain walls to achieve precise control of local structures and properties remains a considerable challenge. Here, we experimentally demonstrate that we can switch from one structural phase to another by laser irradiation, creating domains of different shapes in trilayer graphene. The ability to control the position and orientation of the domain walls leads to fine control of the local structural phases and properties of graphene, offering a simple but effective approach to create artificial two-dimensional materials with designed atomic structures and electronic and optical properties., Laser on trilayer graphene: stack switch with a difference Heat from a laser changes how atoms stack up within trilayer graphene, providing a simple and effective approach for fabricating new materials with interesting optical and electronic properties. Mengjian Zhu of China’s National University of Defense Technology and colleagues used laser light to switch regions within trilayer graphene from one type of atomic layering to another. This is interesting, as the properties of trilayer graphene vary depending on how its atoms are stacked up. Zhu and his colleagues found that heat from the laser manipulated the dividing walls separating differently stacked atomic regions within the graphene flakes. This led to a gradual switch from one type of atomic stacking to another, changing the graphene’s properties. The finding could lead to applications for optical storage media and photonic devices.

Published
2020

46. Native Oxide Seeded Spontaneous Integration of Dielectrics on Exfoliated Black Phosphorus

Author

Yue Zheng, Weiwei Cai, Xin Ye, Tao Liu, Chuyun Deng, Yanan Wang, Jing Gao, Xueao Zhang, Hongying Mao, Wei Chen, Du Xiang, Shiqiao Qin, Rui Guo, Qi Ge, and Hang Yang

Subjects
Electron mobility, Materials science, Silicon, Passivation, business.industry, Graphene, Dangling bond, chemistry.chemical_element, law.invention, Atomic layer deposition, Semiconductor, chemistry, law, Optoelectronics, General Materials Science, business, Layer (electronics)
Abstract

Two-dimensional (2D) semiconductors have been a central focus for next-generation electronics and optoelectronics owing to their great potential to extend the scaling limits in a silicon transistor. However, due to the lack of surface dangling bonds in most 2D semiconductors, such as graphene and transition metal dichalcogenides (TMDs), the direct growth of the high-κ film on these 2D materials via an atomic layer deposition (ALD) technique often produces dielectrics with poor quality, which hinders their integration in the modern semiconductor industry. Here, we comprehensively investigate the ALD growth of the Al2O3 layer on 2D exfoliated black phosphorus (BP). Intriguingly, we found that the 2D BP with "silicon-like" characteristics possesses a native surface oxide layer PxOy after air exposure. The PxOy-induced surface dangling bonds enable the spontaneous integration of the high-quality Al2O3 layer on the BP flake without any pretreatments to functionalize the surface. Additionally, the Al2O3 layer could effectively passivate BP to prevent its degradation in ambient conditions, which addresses the most serious problem of the BP material. Moreover, the Al2O3-encapsulated BP field-effect transistor (FET) exhibits good electrical transport performance, with a high hole mobility of ∼420 cm2 V-1 s-1 and electron mobility of ∼80 cm2 V-1 s-1. Moreover, the high-quality Al2O3 layer can also be integrated into the top-gated BP transistor and inverter. Our findings reveal the silicon-like characteristics of BP for the high-κ ALD dielectric growth technology, which promises the seamless integration of 2D BP in the modern semiconductor industry.

Published
2020

48. High Quality Factor Resonant Metasurface with Etchless Lithium Niobate

Author

Xingqiao Chen, Runxue Leng, Ken Liu, Chucai Guo, Zhihong Zhu, Shiqiao Qin, and Jianfa Zhang

Subjects
History, Polymers and Plastics, Electrical and Electronic Engineering, Business and International Management, Atomic and Molecular Physics, and Optics, Industrial and Manufacturing Engineering, Electronic, Optical and Magnetic Materials
Published
2022

49. Enhanced Molecular Infrared Spectroscopy Employing Bilayer Graphene Acoustic Plasmon Resonator

Author

Zhihong Zhu, Jie Luo, Jianfa Zhang, Shiqiao Qin, Wei Xu, and Chunchao Wen

Subjects
Materials science, Spectrophotometry, Infrared, Infrared, Clinical Biochemistry, Infrared spectroscopy, Physics::Optics, Article, law.invention, Resonator, law, Physics::Atomic and Molecular Clusters, molecular vibrational fingerprints, Physics::Chemical Physics, bilayer graphene, Spectroscopy, infrared spectroscopy, Plasmon, acoustic graphene plasmons, business.industry, Graphene, Bilayer, Proteins, General Medicine, Acoustics, Surface Plasmon Resonance, Optoelectronics, Graphite, business, Bilayer graphene, TP248.13-248.65, Biotechnology
Abstract

Graphene plasmon resonators with the ability to support plasmonic resonances in the infrared region make them a promising platform for plasmon-enhanced spectroscopy techniques. Here we propose a resonant graphene plasmonic system for infrared spectroscopy sensing that consists of continuous graphene and graphene ribbons separated by a nanometric gap. Such a bilayer graphene resonator can support acoustic graphene plasmons (AGPs) that provide ultraconfined electromagnetic fields and strong field enhancement inside the nano-gap. This allows us to selectively enhance the infrared absorption of protein molecules and precisely resolve the molecular structural information by sweeping graphene Fermi energy. Compared to the conventional graphene plasmonic sensors, the proposed bilayer AGP sensor provides better sensitivity and improvement of molecular vibrational fingerprints of nanoscale analyte samples. Our work provides a novel avenue for enhanced infrared spectroscopy sensing with ultrasmall volumes of molecules.

Published
2021
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50. High-Performance Photodetectors Based on MoTe

Author

Xuan, Ji, Zongqi, Bai, Fang, Luo, Mengjian, Zhu, Chucai, Guo, Zhihong, Zhu, and Shiqiao, Qin

Abstract

Two-dimensional (2D) materials have got extensive attention for multifunctional device applications in advanced nanoelectronics and optoelectronics, such as field-effect transistors, photodiodes, and solar cells. In our work, we fabricated MoTe

Published
2021

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