9 results on '"Guo, Chucai"'
Search Results
2. Monolayer-graphene-based broadband and wide-angle perfect absorption structures in the near infrared.
- Author
-
Fan, Yansong, Guo, Chucai, Zhu, Zhihong, Xu, Wei, Wu, Fan, Yuan, Xiaodong, and Qin, Shiqiao
- Abstract
Broadband optical absorption structures in the near infrared by coupling monolayer-graphene with periodical metal structures are proposed and demonstrated numerically. Optical absorption of graphene with over-50%-absorption bandwidth up to hundreds of nanometer caused by magnetic dipole resonances and magnetic coupling effect are investigated in detail, and the demonstrated bandwidths are one order higher than those caused by dielectric guiding mode resonances. In addition, the influences of geometrical parameters of structures are fully analyzed and these demonstrated structures show angular-insensitive absorption for oblique incidence in a large angular range. The demonstrated absorption structures in this work provide new design ideas in the realization of advanced graphene-based optoelectronic devices. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
3. Low-Threshold and High-Extinction-Ratio Optical Bistability within a Graphene-Based Perfect Absorber.
- Author
-
Zhang, Zhengzhuo, Sun, Qiaoge, Fan, Yansong, Zhu, Zhihong, Zhang, Jianfa, Yuan, Xiaodong, and Guo, Chucai
- Subjects
- *
OPTICAL bistability , *QUALITY factor , *NONLINEAR optics , *GRAPHENE - Abstract
A kind of graphene-based perfect absorber which can generate low-threshold and high-extinction-ratio optical bistability in the near-IR band is proposed and simulated with numerical methods. The interaction between input light and monolayer graphene in the absorber can be greatly enhanced due to the perfect absorption. The large nonlinear coefficient of graphene and the strong light-graphene interaction contribute to the nonlinear response of the structure, leading to relatively low switching thresholds of less than 2.5 MW/cm2 for an absorber with a Q factor lower than 1000. Meanwhile, the extinction ratio of bistable states in the absorber reaches an ultrahigh value of 47.3 dB at 1545.3 nm. Moreover, the influence of changing the structural parameters on the bistable behaviors is discussed in detail, showing that the structure can tolerate structural parametric deviation to some extent. The proposed bistable structure with ultra-compact size, low thresholds, high extinction ratio, and ultrafast response time could be of great applications for fabricating high-performance all-optical-communication devices. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
4. High-temperature resistant broadband infrared stealth metamaterial absorber.
- Author
-
Quan, Cong, Zou, Jinglan, Guo, Chucai, Xu, Wei, Zhu, Zhihong, and Zhang, Jianfa
- Subjects
- *
INFRARED radiation , *HEAT radiation & absorption , *SOLAR radiation , *MELTING points , *ABSORPTION spectra , *METAMATERIALS - Abstract
In this paper, we propose a broadband infrared stealth metamaterial absorber based on an improved metal-dielectric-metal structure where its top pattern consists of multi-layers. The structure uses high-temperature resistant materials instead of traditional low melting point precious metals and achieves selective thermal radiation in the infrared band. The study shows that with the increase of the number of layers, the absorption peak and bandwidth of the non-atmospheric window band expands. When the thickness of the structure is five layers, it can match well with the atmospheric absorption spectra. The polarization sensitivity and infrared stealth performance at different temperatures of the structure with five-layer are studied in detail. Compared with black body, the selective thermal emitter maintains radiation reduction rates greater than 80% in MWIR and LWIR regions. The high temperature resistant heat emitter proposed by us can be used in spectrally selective thermal radiation, thermal management and thermal camouflage, which has a very promising application prospect. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
5. High-Temperature Quantum Hall Effect in Graphite-Gated Graphene Heterostructure Devices with High Carrier Mobility.
- Author
-
Zhou, Siyu, Zhu, Mengjian, Liu, Qiang, Xiao, Yang, Cui, Ziru, and Guo, Chucai
- Subjects
- *
QUANTUM Hall effect , *CHARGE carrier mobility , *BORON nitride , *CONDENSED matter physics , *GRAPHENE , *TWO-dimensional electron gas - Abstract
Since the discovery of the quantum Hall effect in 1980, it has attracted intense interest in condensed matter physics and has led to a new type of metrological standard by utilizing the resistance quantum. Graphene, a true two-dimensional electron gas material, has demonstrated the half-integer quantum Hall effect and composite-fermion fractional quantum Hall effect due to its unique massless Dirac fermions and ultra-high carrier mobility. Here, we use a monolayer graphene encapsulated with hexagonal boron nitride and few-layer graphite to fabricate micrometer-scale graphene Hall devices. The application of a graphite gate electrode significantly screens the phonon scattering from a conventional SiO2/Si substrate, and thus enhances the carrier mobility of graphene. At a low temperature, the carrier mobility of graphene devices can reach 3 × 105 cm2/V·s, and at room temperature, the carrier mobility can still exceed 1 × 105 cm2/V·s, which is very helpful for the development of high-temperature quantum Hall effects under moderate magnetic fields. At a low temperature of 1.6 K, a series of half-integer quantum Hall plateaus are well-observed in graphene with a magnetic field of 1 T. More importantly, the ν = ±2 quantum Hall plateau clearly persists up to 150 K with only a few-tesla magnetic field. These findings show that graphite-gated high-mobility graphene devices hold great potential for high-sensitivity Hall sensors and resistance metrology standards for the new Système International d'unités. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
6. Spectrally selective radiation infrared stealth based on a simple Mo/Ge bilayer metafilm.
- Author
-
Quan, Cong, Gu, Song, Liu, Ping, Xu, Wei, Guo, Chucai, Zhang, Jianfa, and Zhu, Zhihong
- Subjects
- *
INFRARED radiation , *ATMOSPHERIC radiation , *PRECIOUS metals , *EMISSIVITY , *HEAT radiation & absorption - Abstract
• A spectrally selective radiation infrared stealth metafilm based on a simple bilayer structure is proposed and experimentally demonstrated. • The metafilm uses the common inexpensive metal Mo instead of traditional precious metals and can be easily fabricated. • The metafilm achieves infrared stealth with low emissivity in the atmospheric window and radiation heat dissipation with high emissivity in the non-atmospheric window. In this paper, we propose and demonstrate a spectrally selective radiation infrared stealth metafilm based on a simple bilayer structure. Specifically, we use the common inexpensive metal Mo instead of traditional precious metals and achieve selective thermal radiation in the infrared band. In the atmospheric window band, the absorptivity is relatively low, which can well achieve the purpose of infrared stealth, while in the non-atmospheric window band, the absorptivity acutely increases, with a high absorptivity of 94.89 % at 6.04 μ m , which can achieve better radiation heat dissipation. The experimental results are consistent with the simulation. The average emissivity in the 8–14 μ m atmospheric window band is 0.32, while in the 5–8 μ m non-atmospheric window band is 0.80, which proves the possibility of its practical application. Meanwhile, the metafilm proposed by us can be easily fabricated and can be widely used in the control of infrared thermal radiation, thermal management, and thermal camouflage, which has a very promising application prospect. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
7. Regulation of Thermal Emission Position in Biased Graphene.
- Author
-
Fan, Yansong, Zhang, Zhengzhuo, Zhu, Zhihong, Zhang, Jianfa, Xu, Wei, Wu, Fan, Yuan, Xiaodong, Guo, Chucai, and Qin, Shiqiao
- Subjects
- *
GRAPHENE , *FERMI level , *TEMPERATURE distribution , *MOLECULAR spectra - 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. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
8. High quality factor resonant metasurface with etchless lithium niobate.
- Author
-
Chen, Xingqiao, Leng, Runxue, Liu, Ken, Guo, Chucai, Zhu, Zhihong, Qin, Shiqiao, and Zhang, Jianfa
- Subjects
- *
LITHIUM niobate , *QUALITY factor , *OPTICAL modulation , *BEAM steering , *OPTICS , *TELECOMMUNICATION - Abstract
Actively tunable metasurfaces have widespread applications in optics from light modulation, beam steering to LiDAR and many others. Recently, lithium niobate (LN) based metasurfaces have attracted significant attention for their great potentials in integrated electro-optically tunable metadevices. However, the hardness and chemical inactivity of LN make it difficult to process, which severely limits the quality (Q) factors and performance of LN based metasurfaces. In this paper, a type of high Q etchless LN resonant metasurface is experimentally demonstrated. The metasurface shows a measured Q factor of 563 around the telecom wavelength and even higher Q factors are expected to be realized using similar designs in the future. This work represents an important progress for LN resonant metasurfaces and paves the way for the development of high performance electro-optically tunable LN metadevices. • Demonstrate a type of high-Q LN resonant metasurface in telecom wavelength range. • Uses a dielectric-loaded design with subwavelength patterns. • The LN is etchless to avoid the fabrication difficulty. • The measured Q factor of 563 is almost one order higher than the previous work. • Paves the way for the development of high performance EO tunable LN metadevices. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
9. Facile synthesis of ZnO/PdSe2 core-shell heterojunction for efficient photodetector application.
- Author
-
Shi, Zhengtian, Qi, Xiangqian, Zhang, Zhaokun, Zhang, Jianfa, Guo, Chucai, Liu, Ken, Xu, Wei, Xu, Jun, and Zhu, Zhihong
- Subjects
- *
HETEROJUNCTIONS , *CHEMICAL vapor deposition , *ZINC oxide , *ZINC oxide films , *PHOTOELECTRIC devices , *PHOTODETECTORS - Abstract
ZnO/PdSe 2 core-shell heterojunction nanorod arrays exhibit higher photocurrent (≈0.75 mA cm−2) and faster response (T off/ZnO@PdSe2 =4.5 ms, T on/ZnO@PdSe2 =4.5 ms) than most of reported commercial ZnO and ZnO composite nanomaterials. [Display omitted] • ZnO/PdSe 2 core-shell HNAs were synthesized by a low temperature selenization method for the first time. • ZnO/PdSe 2 core-shell HNAs possess stable structures and superb active interfaces. • Ultrafast response and high photocurrent density were achieved. • A more profound mechanism for the ZnO/PdSe 2 photoelectrochemical (PEC) reaction was proposed. Palladium diselenide (PdSe 2), a group-10 transition metal dichalcogenide with great optoelectronic and electrical properties due to unique structure, has gained increasing attention in the scientific community. Herein, we demonstrate an effective strategy to synthesis of ZnO/PdSe 2 core–shell heterojunction nanorod arrays (HNAs) through a simple two-step method for the first time. A Pd film was deposited on ZnO NAs by an electron beam evaporation method at first. Then, the selenization process was completed by a chemical vapor deposition (CVD) method. Furthermore, the photoelectric performances of electrodes based on ZnO NAs, PdSe 2 film and ZnO/PdSe 2 core–shell HNAs were investigated, respectively. The ZnO/PdSe 2 core–shell HNA represents better responsitivity with higher photocurrent density (1.3 mA cm−2) comparing to the ZnO NA (0.03 mA cm−2), indicating that the ZnO/PdSe 2 samples are more suitable for photoelectric devices. Besides, photoelectric performance of this work is better than most of reported commercial ZnO and ZnO composite nanomaterials. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
Catalog
Discovery Service for Jio Institute Digital Library
For full access to our library's resources, please sign in.