Your search keyword '"Wang, Zhanliang"' showing total 47 results

1. Experimental and Numerical Analysis of the Ribbed Reinforced Concrete Fracture Behavior Based on the Mesoscale FE Model

Author

Wang, Zhanliang, Zhang, Wei, and Huang, Yiqun

Published

2023

2. A Staggered Vane-Shaped Slot-Line Slow-Wave Structure for W-Band Dual-Sheet Electron-Beam-Traveling Wave Tubes.

Author

Wang, Yuxin, Guo, Jingyu, Dong, Yang, Xu, Duo, Zheng, Yuan, Lu, Zhigang, Wang, Zhanliang, and Wang, Shaomeng

Subjects

TRAVELING-wave tubes, MASS production, SHEET metal, MICROFABRICATION

Abstract

A staggered vane-shaped slot-line slow-wave structure (SV-SL SWS) for application in W-band traveling wave tubes (TWTs) is proposed in this article. In contrast to the conventional slot-line SWSs with dielectric substrates, the proposed SWS consists only of a thin metal sheet inscribed with periodic grooves and two half-metal enclosures, which means it can be easily manufactured and assembled and has the potential for mass production. This SWS not only solves the problem of the dielectric loading effect but also improves the heat dissipation capability of such structures. Meanwhile, the SWS design presented here covers a −15 dB S11 frequency range from 87.5 to 95 GHz. The 3-D simulation for a TWT based on the suggested SWS is also investigated. Under dual-electron injection conditions with a total voltage of 17.2 kV and a total current of 0.3 A, the maximum output power at 90 GHz is 200 W, with a 3 dB bandwidth up to 4 GHz. With a good potential for fabrication using microfabrication techniques, this structure can be a good candidate for millimeter-wave TWT applications. [ABSTRACT FROM AUTHOR]

Published

2024

3. Imprinted CNTs field emission cathode for electron brushing.

Author

Wang, Zhanliang, Lin, Zhanpeng, Yan, Lei, Xu, Zhifeng, Liu, Jianlong, He, Zhiyuan, Jianmucuo, Dongzhi, Jiang, Ruirui, and Gong, Yubin

Published

2024

4. Experimental and Numerical Study of Concrete Fracture Behavior with Multiple Cracks Based on the Meso-Model.

Author

Wang, Zhanliang, Zhang, Wei, and Huang, Yiqun

Subjects

*CONCRETE fractures, *CRACKING of concrete, *ENERGY dissipation, *SURFACE potential, *ENERGY consumption, *COHESIVE strength (Mechanics), *MORTAR

Abstract

In this paper, a series of experimental and numerical studies were carried out to investigate the effect of multiple cracks on concrete fracture behavior. Seven groups of double-crack concrete three-point bending (TPB) experiments with different crack lengths and different crack distances were carried out. The experimental results showed that the bearing capacity of double-crack specimens was slightly larger than the standard specimen with one central crack. Additionally, with an increase in the second crack length or with a crack distance reduction, the concrete's bearing capacity increased correspondingly. Based on the experiments, a numerical meso-model was developed based on applying cohesive elements. The aggregate, mortar, interface transition zone (ITZ), and potential fracture surfaces were explicitly considered in the model. In particular, cohesive elements were used to characterize the mechanical behavior of the ITZ and potential fracture surfaces. A modified constitutive concrete model was developed by considering the potential fracture surfaces' damage relation and friction effect. The accuracy of the developed meso-model was validated through a comparison between simulation and experiments. Based on meso-models, the influence of multiple cracks on the concrete bearing capacity was investigated by analyzing the energy evolution. The analysis results showed that the bearing capacity has a linear relation with the proportion of mode II energy consumption during the fracture process, which explains why specimens with multiple cracks have a slightly larger bearing capacity than the standard specimens. In summary, this study has found that in three-point bending fracture tests primarily characterized by mode I fractures, the presence of multiple cracks near the main crack slightly enhances the load-bearing capacity of the specimens. This is attributed to a slight increase in internal energy dissipation associated with the presence of these multiple cracks. [ABSTRACT FROM AUTHOR]

Published

2023

5. A Novel Staggered Double-Segmented Grating Slow-Wave Structure for 340 GHz Traveling-Wave Tube.

Author

Wang, Zechuan, Zhu, Junwan, Lu, Zhigang, Duan, Jingrui, Chen, Haifeng, Wang, Shaomeng, Wang, Zhanliang, Gong, Huarong, and Gong, Yubin

Subjects

TRAVELING-wave tubes, SUBMILLIMETER waves

Abstract

In this paper, a novel staggered double-segmented grating slow-wave structure (SDSG-SWS) is developed for wide-band high-power submillimeter wave traveling-wave tubes (TWTs). The SDSG-SWS can be considered as a combination of the sine waveguide (SW) SWS and the staggered double-grating (SDG) SWS; that is, it is obtained by introducing the rectangular geometric ridges of the SDG-SWS into the SW-SWS. Thus, the SDSG-SWS has the advantages of the wide operating band, high interaction impedance, low ohmic loss, low reflection, and ease of fabrication. The analysis for high-frequency characteristics shows that, compared with the SW-SWS, the SDSG-SWS has higher interaction impedance when their dispersions are at the same level, while the ohmic loss for the two SWSs remains basically unchanged. Furthermore, the calculation results of beam–wave interaction show that the output power is above 16.4 W for the TWT using the SDSG-SWS in the range of 316 GHz–405 GHz with a maximum power of 32.8 W occurring at 340 GHz, whose corresponding maximum electron efficiency is 2.84%, when the operating voltage is 19.2 kV and the current is 60 mA. [ABSTRACT FROM AUTHOR]

Published

2023

6. An Angular Radial Extended Interaction Amplifier at the W Band.

Author

Dong, Yang, Wang, Shaomeng, Guo, Jingyu, Wang, Zhanliang, Gong, Huarong, Lu, Zhigang, Duan, Zhaoyun, and Gong, Yubin

Subjects

ELECTRON gun, ELECTRON beams, KLYSTRONS

Abstract

In this paper, an angular radial extended interaction amplifier (AREIA) that consists of a pair of angular extended interaction cavities is proposed. Both the convergence angle cavity and the divergence angle cavity, which are designed for the converging beam and diverging beam, respectively, are investigated to present the potential of the proposed AREIA. They are proposed and explored to improve the beam–wave interaction capability of W-band extended interaction klystrons (EIKs). Compared to conventional radial cavities, the angular cavities have greatly decreased the ohmic loss area and increased the characteristic impedance. Compared to the sheet beam (0°) cavity, it has been found that the convergence angle cavity has a higher effective impedance and the diverging beam has a weaker space-charge effect under the same ideal electron beam area; the advantages become more obvious as the propagation distance increases. Particle-in-cell (PIC) results have shown that the diverging beam (8°) EIA performs better at an output power of 94 GHz under the condition of lossless, while the converging beam (−2°) EIA has a higher output power of 6.24 kW under the conditions of ohmic loss, an input power of 0.5 W, and an ideal electron beam of 20.5 kV and 1.5 A. When the loss increases and the beam current decreases, the output power of the −2° EIA can be improved by nearly 30% compared to the 0° EIA, and the −2° EIA has a greatly improved beam–wave interaction capacity than conventional EIAs under those conditions. In addition, an angular radial electron gun is designed. [ABSTRACT FROM AUTHOR]

Published

2023

7. Simulation Design of G -Band FWG TWT Amplifier Enhanced by π -Mode Extended Interaction.

Author

Shi, Ningjie, Zhang, Changqing, Tian, Hanwen, Wang, Shaomeng, Wang, Zhanliang, Zhang, Ping, Tang, Tao, Duan, Zhaoyun, Lu, Zhigang, Gong, Huarong, and Gong, Yubin

Subjects

TRAVELING-wave tubes, COPLANAR waveguides, SUBSTRATE integrated waveguides, DIELECTRIC waveguides, SHORT circuits, JOB performance

Abstract

This article studies and summarizes the operating characteristics of a ${G}$ -band folded waveguide traveling wave tube (TWT) amplifier enhanced by the $\pi $ -mode extended interaction cavities. Compared with conventional ${G}$ -band TWTs, the proposed amplifier can at once obtain a higher gain in a shorter interaction circuit length and ensure a proper operating bandwidth. The key of the design is introducing the $\pi $ -mode multigap resonant cavity with alternating wide and narrow slots, which will improve the working performance of the whole device by shortening the length of the interaction circuit, enhancing its interaction effect, and improving its gain of unit length. In this design, the operation bandwidth is expanded by stagger tuning technique. In addition, the influence of cavity loss is examined so that the optimal performance is achieved. The PIC simulation results show that when the operating voltage is 21 kV and the operating current 80 mA, the maximum average output power of the designed TWT amplifier is 65.78 W at 217.4 GHz, which is corresponding to the maximum gain and efficiency of 37.38 dB and 3.9%, respectively. The gain per unit length is 12.64 dB/cm and the 3-dB bandwidth is 3.5 GHz. [ABSTRACT FROM AUTHOR]

Published

2022

8. Experimental Investigation of a Shape-Optimized Staggered Double-Vane Slow-Wave Structure for Terahertz Traveling-Wave Tubes.

Author

Jiang, Shengkun, Yang, Guang, Wang, Zhanliang, Wang, Xin, Zhang, Xuanming, Lyu, Zhifang, Tang, Tao, Gong, Huarong, Gong, Yubin, and Duan, Zhaoyun

Subjects

TRAVELING-wave tubes, PHASE velocity, TRANSMISSION of sound, QUANTUM cascade lasers, PHASE change materials

Abstract

Enormous concerns focus on the high-power and wide bandwidth traveling-wave tube (TWT) for its outstanding performance. In this article, a shape-optimized staggered double-vane slow-wave structure (SWS) for terahertz (THz) sheet beam TWT is proposed. The shape-optimized staggered double-vane SWS takes the advantages of higher interaction impedance, lower transmission loss, and lower phase velocity than conventional staggered double-vane SWSs. The shape-optimized staggered double-vane SWS with 85 periods is designed, fabricated, and cold tested. The measured transmission loss of the shape-optimized staggered double-vane SWS is less than 0.79 dB/cm in the frequency range of 0.211–0.26 THz, which is in good agreement with the simulation results. Furthermore, the beam–wave interaction analysis of a sheet beam TWT with this SWS is given. The output power is predicted to be >100 W with 3-dB bandwidth of >50 GHz. The results show that the shape-optimized staggered double-vane SWS is a very promising scheme to construct a high-power and wideband THz TWT for future applications such as communication and imaging. [ABSTRACT FROM AUTHOR]

Published

2022

9. Q-Band Helix Traveling-Wave Tube With High Efficiency by Helix Pitch and Diameter Profiling for Potential Application in the Next Generation Wireless Communication System.

Author

Zhang, Pu, Wang, Chuanchao, Li, Ying, Yang, Guang, Huang, Silong, Cheng, Hongxia, Wang, Shaomeng, Wang, Zhanliang, Gong, Huarong, Gong, Yubin, and Duan, Zhaoyun

Subjects

TRAVELING-wave tubes, COMPUTER engineering, WIRELESS communications, SLOW wave structures, STANDING waves, DIAMETER, COPLANAR waveguides

Abstract

A $Q$ -band traveling-wave tube (TWT) with profiled helix pitches and profiled inner diameters of slow wave structure (SWS) is proposed. The transmission characteristics of the $Q$ -band TWT are simulated by the Computer Simulation Technology (CST). In the operating frequency band (36.5–41.5 GHz), the simulated voltage standing wave ratio (VSWR) is less than 1.5. In addition, the beam–wave interaction is simulated to predict the performance of the $Q$ -band TWT when the beam voltage and beam current are 8.5 kV and 60 mA, respectively, and the axial focusing magnetic field is 0.4 T. In the operating frequency band, the self-oscillation is well suppressed, and the device efficiency of the $Q$ -band TWT exceeds 63.5%, and the saturated output power and gain exceed 83 W and 45 dB, respectively, especially the device efficiency can reach the maximum of 69.5% at 37 GHz. When it is backed off 6 dB from the saturation, the device efficiency exceeds 40.5%, up to 42.7% at 39 GHz. Preliminary experiments have confirmed the design. These results show that the proposed $Q$ -band TWT has important applications to the next generation wireless communication system with high efficiency. [ABSTRACT FROM AUTHOR]

Published

2022

10. Crystal growth and magnetic property of YFeO 3 crystal

Author

WU, ANHUA, SHEN, HUI, XU, JUN, WANG, ZHANLIANG, JIANG, LINWEN, LUO, LIQING, YUAN, SHUJUAN, CAO, SHIXUN, and ZHANG, HUAIJIN

Published

2012

11. A Ka-Band Angular Log-Periodic Meander-Line SWS Supported by Diamond Rods.

Author

Wang, Zhanliang, Liu, Xing, Hu, Qiang, Gong, Yubin, Duan, Zhaoyun, Gong, Huarong, Lu, Zhigang, Wang, Shaomeng, and Feng, Jinjun

Subjects

*TRAVELING-wave tubes, *SLOW wave structures, *TELECOMMUNICATION systems, *LASER machining, *DIAMONDS

Abstract

The angular log-periodic meander-line traveling wave tube (TWT) is a kind of low voltage, small-sized, high power, low cost, on chip amplifiers, and considered as a key part of the advanced communication systems, the future biomedical applications and the next electronic counter measure (ECM) instruments et al. Here, an angular log-periodic meander-line TWT is presented in this article. The angular log-periodic meander-line slow wave structure (SWS) is supported by two diamond rods. The dispersion and the impedance characteristics are analyzed in detail. In order to reduce the reflection loss, a gradual ridged waveguide is connecting the input–output standard rectangular waveguide to the meander-line SWS. The particle in cell (PIC) simulations show that the output power of the TWT can reach 55 W at 34 GHz with the operation voltage of 1800 V and the beam current of 0.2 A. The SWS is manufactured by a laser machine with Molybdenum sheet. The assembled TWT is tested and the results show that the ${S}_{{11}}$ is less than −10 dB at 30–39 GHz. The ${S}_{{21}}$ mismatch between the simulated and the measurement is discussed at the end. [ABSTRACT FROM AUTHOR]

Published

2022

12. A 0.14 THz Angular Radial Extended Interaction Oscillator.

Author

Dong, Yang, Wang, Shaomeng, Guo, Jingyu, Wang, Zhanliang, Tang, Tao, Gong, Huarong, Lu, Zhigang, Duan, Zhaoyun, and Gong, Yubin

Subjects

ELECTRON beams, VOLTAGE

Abstract

A 0.14 THz angular radial extended interaction oscillator (AREIO) is proposed in this article. The characteristic impedance (${R}/{Q}$), the normalized equivalent conductance (${g}_{e}$), and the starting condition of the cavity are calculated and analyzed. When the metal loss is considered, in order to achieve the starting condition, it is necessary to increase the period length (${p}$) to improve $\vert {g}_{e}\vert $. The performance of the AREIO is simulated by particle-in-cell (PIC). The voltage tuning range and the output performance under different angular angles of the cavity are investigated. Under the condition of lossless and the electron beam of 11.5 kV and 1.5 A, the peak output power and interaction efficiency of the AREIO (8°) are 5.46 kW and 31.7%, which have increased by 24.1% and 6.2% in comparison with conventional sheet beam. When considering the metal loss, the optimal angular angle will decrease to 4°. In addition, the cavity is fabricated and tested, and the results of ${S}_{{11}}$ in operating mode are consistent with the simulation. [ABSTRACT FROM AUTHOR]

Published

2022

13. The influence of catalyst layer morphology on the electrochemical performance of DMFC anode

Author

Wang, Zhanliang, Liu, Yang, and Linkov, Vladimir M.

Published

2006

14. Experimental Investigation of an Electron-Optical System for Terahertz Traveling-Wave Tubes.

Author

Jiang, Shengkun, Wang, Xin, Zhang, Xuanming, Lyu, Zhifang, Wang, Zhanliang, Gong, Huarong, Gong, Yubin, and Duan, Zhaoyun

Subjects

TRAVELING-wave tubes, ELECTRON gun, ELECTRON beams, SUBMILLIMETER waves, SLOW wave structures, TUNNEL ventilation

Abstract

A novel electron-optical system (EOS) for ${G}$ -band traveling-wave tubes (TWT) is investigated by simulation and verified by experiment. The EOS includes a sheet beam electron gun, a tunable periodic cusped magnetic focusing (TPCMF), and a collector. An elliptical focus electrode (FE) featuring a simple geometry and easy fabrication is utilized to compress the pencil beam into the sheet beam with a cross section of 0.4 mm $\times0.1$ mm. The electron gun with a cylindrical cathode of 0.8 mm diameter generates the sheet beam with voltage of 22 kV and current of 115 mA. Based on the sheet beam electron gun, the TPCMF with easy assembly and compact size is then proposed. The experimental results show that the beam transmission is 92.1% within a beam tunnel (its length 21.2 mm and cross section 0.8 mm $\times0.15$ mm). The EOS is suitable for ${G}$ -band TWT. [ABSTRACT FROM AUTHOR]

Published

2021

15. A Simulation Method Based on Nonlinear Theory for Noise Analysis in Traveling-Wave Tube.

Author

Guo, Zugen, Zhang, Ruifeng, Ji, Rujing, Lan, Feng, Zhou, Xibang, Wang, Zhanliang, Lu, Zhigang, Duan, Zhaoyun, Gong, Yubin, and Gong, Huarong

Subjects

TRAVELING-wave tubes, NONLINEAR theories, NOISE, ELECTRON beams, ELECTROMAGNETIC waves, STANDING waves, QUANTUM noise, LAGRANGE equations

Abstract

In this article, we propose a simulation method to investigate the noise mechanism of traveling-wave tube (TWT). Based on the nonlinear theory of Lagrangian description, 1-D noise model is established to analyze the shot noise and the velocity noise of the electron beam in the drift space, which clearly shows that the beam noise propagates along the electron beam with standing wave shape. The shot noise and the velocity noise can be periodically converted into each other along electron beam transmission, which is consistent with the prediction of the classical noise theory developed by Pierce and Danielson (1954). Using the nonlinear beam–wave interaction theory, the evolution process of the shot noise and the velocity noise of the electron beam transforming to the electromagnetic wave in TWT is illustrated. The calculated results show that the input position of the slow wave circuit may affect the noise power spectral density (NPSD) of the device. The proposed method can provide more intuitive and simple images to explain the noise mechanism of TWT. [ABSTRACT FROM AUTHOR]

Published

2021

16. Determination of Urine Sex Hormones and Related Metabolites in Male Obese Children: 850: June 1 1:45 PM - 2:00 PM

Author

Yan, Yi, Xie, Minhao, Wang, Ke, Li, Liang, Wang, Zhanliang, and Zhang, Yinong

Published

2011

17. Improved Model for Beam–Wave Interaction With Ohmic Losses and Reflections of Sheet Beam Traveling Wave Tubes.

Author

Tian, Hanwen, Shi, Ningjie, Wang, Zhanliang, Wang, Shaomeng, Duan, Zhaoyun, Gong, Huarong, Lu, Zhigang, Paoloni, Claudio, Feng, Jinjun, and Gong, Yubin

Subjects

TRAVELING-wave tubes, SPACE charge, ALGORITHMS, ELECTROMAGNETIC fields, MAGNETIC fields, WIND turbine blades, REFLECTIONS

Abstract

In this article, an improved model for the beam–wave interaction of sheet beam in traveling wave tubes (TWTs) considering ohmic losses and reflections is presented. The ohmic losses are obtained by field analysis and equivalent method. The space charge magnetic field is derived from the active Helmholtz’s equation. An algorithm to obtain the S-matrix by the equivalent circuit method is presented. The relativistic Boris method is applied to accelerate macroparticles. The exchanged power is computed by the work the electromagnetic field applied to the macroparticles. The theoretical model is applied for validation to a G-band staggered double vane TWT and validated in comparison with CST Particle Studio and simulations without losses and reflections. The convergence of this algorithm is also discussed. The simulation time of the model is substantial faster than 3-D particle-in-cell (PIC) simulations. [ABSTRACT FROM AUTHOR]

Published

2021

18. Electron-optical system for dual radial sheet beams for Ka-band cascaded angular log-periodic strip-line traveling wave tube.

Author

He, Tenglong, Wang, Shaomeng, Wang, Zhanliang, Shao, Wei, Xu, Duo, Li, Xinyi, Wang, Hexin, Gong, Huarong, Lu, Zhigang, Duan, Zhaoyun, Aditya, Sheel, and Gong, Yubin

Subjects

TRAVELING-wave tubes, CURVED surfaces, DISTRIBUTION (Probability theory), ELECTRON beams

Abstract

A novel electron-optical system is proposed for dual azimuthally stacked radial sheet electron beams (ARSEBs). The two sheet beams are emitted from curved surfaces of two cathodes and are focused by a focusing electrode, which is carefully designed to produce a symmetric field distribution for the two beams and to avoid interference between the beams. A common tunable periodic cusped magnetic focusing system is also designed to focus the two ARSEBs. The dual sheet beams are used in a traveling wave tube (TWT) consisting of a cascade of two azimuthally supported angular log-periodic strip-line (ASALS) slow-wave structures (SWSs). The transmission efficiency in the presence of beam–wave interaction is 93%. The particle-in-cell simulation results show that for a beam voltage of 4400 V and a current of 0.39 A, the proposed cascaded TWT has a maximum gain of 32.5 dB at 35 GHz and a maximum output power of 180 W; this is a significant gain improvement over a TWT using a single ASALS SWS. [ABSTRACT FROM AUTHOR]

Published

2021

19. Investigation of Sine Groove Waveguide Slow Wave Structure for Terahertz Traveling Wave Tube.

Author

Lu, Zhigang, Wen, Ruidong, Wang, Zhanliang, Gong, Huarong, and Gong, Yubin

Subjects

TRAVELING-wave tubes, SLOW wave structures, TERAHERTZ materials, COPLANAR waveguides, SUBMILLIMETER waves

Abstract

A novel sine groove waveguide slow wave structure (SGW-SWS), originated from the sine waveguide (SW), is proposed for a wideband terahertz (THz) traveling wave tube (TWT). SGW-SWS not only has high interaction impedance in a relatively wide frequency band, but also has a wide beam tunnel. In addition, it can be fabricated using the Nano-Computer Numerical Control (CNC) milling techniques. The high-frequency simulation results show that, under the same dispersion, the passband of SGW-SWS is 23 GHz wider than that of SW-SWS, and the average interaction impedance of SGW-SWS is higher than that of SW-SWS in the whole passband. And the transverse dimension of beam tunnel is independent of the dispersion characteristics of SGW-SWS, so the beam current can be further increased by enlarging the size of beam tunnel. Moreover, the particle-in-cell (PIC) simulation results reveal that the saturated power and electronic efficiency of SGW-TWT in the frequency range of 201–260 GHz are more than 84.9 W and 2.72%, respectively, when the operating voltage is 20.8 kV and the beam current is 150 mA. [ABSTRACT FROM AUTHOR]

Published

2021

20. Dielectric-Supported Staggered Dual Meander-Line Slow Wave Structure for an E-Band TWT.

Author

Wang, Hexin, Wang, Shaomeng, Wang, Zhanliang, Li, Xinyi, Xu, Duo, Duan, Zhaoyun, Lu, Zhigang, Gong, Huarong, Aditya, Sheel, and Gong, Yubin

Subjects

SLOW wave structures, TRAVELING-wave tubes

Abstract

In this article, a novel dielectric-supported staggered dual-meander-line (DS-SDML) planar slow-wave structure (SWS) is proposed for a traveling wave tube (TWT) working at ${E}$ -band. The proposed staggered arrangement of meander-lines (MLs) leads to a stronger beam–wave interaction and achieves higher output power as compared to the symmetric arrangement. The input–output couplers have been designed by using staggered stepped double ridge waveguide, to connect the standard ${E}$ -band rectangular waveguide and the DS-SDML SWS. An attenuator and pitch tapering have been applied to the proposed SWS to suppress the unwanted frequencies and to improve the output power. Particle-in-cell (PIC) simulation results show that for an 11.8-kV, 200-mA sheet-beam, the output power can reach 283 W at 75 GHz, with a maximum gain and electronic efficiency of 34.5 dB and 11.9%, respectively. [ABSTRACT FROM AUTHOR]

Published

2021

21. Study on an X-Band Sheet Beam Meander-Line SWS.

Author

Wang, Zhanliang, Du, Feifei, Li, Shifeng, Hu, Qiang, Duan, Zhaoyun, Gong, Huarong, Gong, Yubin, and Feng, Jinjun

Subjects

*TRAVELING-wave tubes, *SLOW wave structures, *SPACE exploration, *POWER amplifiers, *PLASMA sheaths

Abstract

The miniaturized traveling wave tube (TWT) is a kind of high-efficiency, high-power, long-lifetime power amplifier which is an attractive choice for many applications, such as outer space exploration, phased array radar detection, unmanned aerial vehicle (UAV) communication, and on-chip application. In this article, a sheet beam miniaturized TWT with V-shaped meander-line slow wave structure (SWS) supported by two trapezoidal ceramic rods is designed. First, the dispersion characteristics, the impedance characteristics, and the S-parameters of the V-shaped meander-line SWS are analyzed in detail. Then, the particle-in-cell (PIC) simulation results predict that the TWT can produce 512-W output power driven by a 7.1 kV, 0.3-A sheet beam with a rectangular cross-sectional area of 3.5 mm $\times0.1$ mm. The TWT can cover the whole ${X}$ -band when the operation voltage shift from 7.1 to 9.1 kV. At last, the V-shaped meander-line SWS is manufactured, assembled, and tested. The good agreement between the simulated and the measured ${S} _{\mathbf {11}}$ has been achieved and the mismatch between the simulated and the measured ${S} _{\mathbf {21}}$ has been discussed at the end. [ABSTRACT FROM AUTHOR]

Published

2020

22. 0.2-THz Traveling Wave Tube Based on the Sheet Beam and a Novel Staggered Double Corrugated Waveguide.

Author

Lu, Zhigang, Ge, Weihua, Wen, Ruidong, Wang, Zhanliang, Gong, Huarong, Wei, Yanyu, and Gong, Yubin

Subjects

TRAVELING-wave tubes, SLOW wave structures, TERAHERTZ materials

Abstract

A novel slow wave structure (SWS), named staggered double corrugated waveguide (SDCW), is proposed for the development of wideband high-power terahertz (THz) traveling wave tubes (TWTs). The SDCW-SWS not only has the wideband characteristic of staggered double grating (SDG) but also has the high interaction impedance characteristic of symmetrical double grating. In addition, its tunnel width is independent of the lower cutoff frequency and can be further increased. Numerical Eigen mode calculations show that, under the same dispersion, the passband of SDCW-SWS is increased by more than 10 GHz compared with SDG-SWS, and the average interaction impedance at 195 GHz is increased by about 62%. A particle-in-cell simulation analysis confirms that the average output power, saturated gain, and electron efficiency of SDCW-TWT at 195 GHz are ~110 W, ~20.34 dB, and ~5.46%, respectively, when the operating voltage is 20 kV and the beam current is 100 mA. Therefore, SDCW is a promising slow wave circuit of wideband high-power THz traveling wave amplifier. [ABSTRACT FROM AUTHOR]

Published

2020

23. Investigation of Double Tunnel Sine Waveguide Slow-Wave Structure for Terahertz Dual-Beam TWT.

Author

Lu, Zhigang, Zhu, Meiling, Ding, Kesen, Wen, Ruidong, Ge, Weihua, Wang, Zhanliang, Tang, Tao, Gong, Huarong, and Gong, Yubin

Subjects

TRAVELING-wave tubes, TUNNELS, PHASE velocity, ELECTRON beams, ELECTRON tunneling, TRAVELING waves (Physics), SUBMILLIMETER waves

Abstract

Traveling wave tube (TWT) is an attractive solution for wideband and high-power sources or amplifiers in the terahertz (THz) band. In this article, a novel slow-wave structure (SWS) for TWT, named double tunnel sine waveguide (DTSW), which is based on sine waveguide (SW), is proposed. The following key technologies are adopted: 1) the rectangular holes, at which the operating mode is cutoff, are alternately opened on the sine-shaped ridges to form two electron beam tunnels and 2) the lower surface of rectangular holes is flush with the top of sine-shaped ridges. Compared with the SW-SWS, DTSW-SWS has the wider operating band and higher interaction impedance under the condition that the phase velocity of the two SWSs is at the same level. In addition, DTSW-SWS is simple in structure and easy to fabricate. The particle-in-cell simulation results reveal that DTSW-TWT has an output power of more than 202 W in the frequency range of 202–255 GHz with the maximum power of ~405 W and electron efficiency of ~9.8% at 215 GHz, under the operating voltage of 23 kV and beam current of 180 mA. Therefore, the DTSW should be considered as a promising SWS for the high-power and wideband THz traveling wave amplifier. [ABSTRACT FROM AUTHOR]

Published

2020

24. Investigation of angular log-periodic folded groove waveguide slow-wave structure for low voltage Ka-band TWT.

Author

Wang, Hexin, Wang, Shaomeng, Wang, Zhanliang, Li, Xinyi, Xu, Duo, He, Tenglong, Tang, Tao, Gong, Huarong, Lu, Zhigang, Duan, Zhaoyun, Aditya, Sheel, and Gong, Yubin

Subjects

LOW voltage systems, TRAVELING-wave tubes, DISPERSION relations, INVESTIGATIONS

Abstract

In this paper, a novel angular log-periodic folded groove waveguide (ALFGW) slow-wave structure (SWS) has been investigated theoretically and experimentally for application in Ka-band traveling-wave tubes (TWTs). The dispersion relation for the ALFGW is derived analytically, and the dispersion characteristics are calculated for a Ka-band design. The designed SWS is fabricated using oxygen-free-copper that is silver electroplated. The measured cold-test parameters show good agreement with the simulation results, with S21 varying from −2.7 dB to −4.8 dB and S11 better than −13.6 dB over the frequency range of 30–38 GHz. Simulations of beam–wave interactions using a 4850 V and 0.4 A sheet beam with a high aspect ratio of 28:1 indicate an output power of 128 W, corresponding to a maximum gain and electronic efficiency of 18.1 dB and 6.6%, respectively. Due to the log-periodic form, a higher output power, higher efficiency, wider bandwidth, and lower operating voltage are achieved as compared to a TWT based on the conventional folded groove waveguide (FGW) SWS. These results show that the proposed ALFGW SWS has good potential for application in relatively high-power wideband TWTs. [ABSTRACT FROM AUTHOR]

Published

2020

25. An Active Transmission Matrix-Based Nonlinear Analysis for Folded Waveguide TWT.

Author

Zhang, Ruifeng, Gong, Huarong, Lin, Xiaoyi, Wang, Tieyang, Xiao, Xiaoyi, Wang, Zhanliang, Duan, Zhaoyun, Gong, Yubin, Feng, Jinjun, and Travish, Gil

Subjects

NONLINEAR analysis, TRAVELING-wave tubes, ELECTROMAGNETIC waves, ELECTRON beams

Abstract

A large signal beam-wave interaction model for the analysis of folded waveguide traveling wave-tube (FWG TWT) is proposed. The slow-wave structure is modeled as a sequence of coupled resonant cavities. The electron beam is treated as a current source that can induce electromagnetic waves in the cavity. The beam-wave interacting process is modeled as an active matrix. Compared with the other models only calculating the in-band characteristic of FWG TWT, our model can provide characteristic analysis in both in-band and near cutoff regions, and thus broaden operating bandwidth and suppress oscillation. As verification, two FWG TWT examples were designed by using our model. Its performances predicted by our code agree well with that obtained by the experiment and particle-in-cell software, respectively. [ABSTRACT FROM AUTHOR]

Published

2020

26. Characterization of Metamaterial Slow-Wave Structure Loaded With Complementary Electric Split-Ring Resonators.

Author

Wang, Xin, Duan, Zhaoyun, Zhan, Xirui, Wang, Fei, Li, Shifeng, Jiang, Shengkun, Wang, Zhanliang, Gong, Yubin, and Basu, B. N.

Subjects

ELECTRIC resonators, BACKWARD wave oscillators, CURRENT distribution, KLYSTRONS, MICROWAVE circuits

Abstract

We proposed an all-metal metamaterial slow-wave structure (MSWS) that consists of a circular waveguide periodically loaded with complementary electric split-ring resonators (CeSRRs). We set up an equivalent circuit theoretical model of MSWS and analyzed its high-frequency characteristics. Also, based on the surface current distribution on the CeSRR obtained by using the eigenmode solver in the CST Microwave Studio, a method of calculating the resonant frequency of the CeSRR was proposed. Furthermore, an MSWS with RF coupling port was designed, simulated, fabricated, and experimentally characterized. The dispersion characteristics of MSWS obtained by interpreting the experimental transmission characteristics agreed well with those predicted by theory as well as simulation. Based on the results of simulation and experiment, a concept of “resonance-coupling” was proposed for the passband of MSWS for frequencies below the cutoff frequency of an empty circular waveguide. The role of the slot-line in the CeSRR in influencing the performance of MSWS was also analyzed. The proposed MSWS has wide potential applications in vacuum electron devices, such as backward-wave oscillator and extended interaction klystron. [ABSTRACT FROM AUTHOR]

Published

2019

27. Input and Output Couplers for an Oversized Coaxial Relativistic Klystron Amplifier at Ka-Band.

Author

Li, Shifeng, Duan, Zhaoyun, Huang, Hua, Basu, B. N., Wang, Fei, Liu, Zhenbang, He, Hu, Wang, Xin, Wang, Zhanliang, and Gong, Yubin

Subjects

KLYSTRONS, COMPUTER engineering, QUALITY factor, RELATIVISTIC electron beams, TUNNEL design & construction, BELT conveyors, RECTANGULAR waveguides

Abstract

We propose a novel system of input and output couplers, excited in azimuthal symmetric and stable mode of operation, for an oversized coaxial relativistic klystron amplifier (OCRKA) at Ka-band. A mode converter is introduced in the output coaxial waveguide to provide a tunnel for the input waveguide and fix the inner and outer conductors of the OCRKA. After characterizing the proposed input and output couplers, the high-frequency structure of the OCRKA is designed and then optimized by Computer Simulation Technology. The simulated frequency and loaded quality factor of the input, output, and idler cavities are validated against measurement. Also, the beam–wave interaction of the OCRKA using the proposed input and output couplers is simulated by particle-in-cell software, the average saturated output power of 880 MW of the OCRKA at Ka-band, with 29.3% electronic efficiency and 58-dB saturated gain are obtained. Moreover, no pulse shortening of the output power waveform is observed during the simulation time of 100 ns, which indicates that the proposed input and output couplers can suppress the higher order mode self-oscillation in the Ka-band OCRKA studied here. [ABSTRACT FROM AUTHOR]

Published

2019

28. Study of 220 GHz Dual-Beam Overmoded Photonic Crystal-Loaded Folded Waveguide TWT.

Author

Shi, Ningjie, Wang, Hexin, Xu, Duo, Wang, Zhanliang, Lu, Zhigang, Gong, Huarong, Liu, Diwei, Duan, Zhaoyun, Wei, Yanyu, and Gong, Yubin

Subjects

TRAVELING-wave tubes, PHOTONIC crystals, ELECTRON beams, ELECTRON tubes, CRYSTAL structure, PHOTONIC crystal fibers

Abstract

This paper puts forward a novel dual-beam overmoded folded waveguide (FW) slow-wave structure (SWS), which is loaded with photonic crystals. In this novel structure, the two electron beams pass through the small gaps between the photonic crystal structures and the FW; the dimension of the FW is twice larger than that of the fundamental mode structure. The novel dual-beam photonic crystal overmoded FW traveling-wave tube (TWT) is proposed on the basis of the SWS. And, a mode converter is introduced to achieve the connection between the SWS and the input/output structure, and the mode transformation. At the operating voltage of 21.2 kV and the operating current of 320 mA, the proposed TWT can generate 128 W of output power at 220 GHz, and its 3-dB bandwidth is 7 GHz, ranging from 216 to 223 GHz. [ABSTRACT FROM AUTHOR]

Published

2019

29. 3-D Fast Nonlinear Simulation for Beam–Wave Interaction of Sheet Beam Traveling-Wave Tube.

Author

Tian, Hanwen, Lu, Zhigang, Shao, Wei, Wang, Zhanliang, Ma, Jialu, He, Tenglong, Gong, Huarong, Duan, Zhaoyun, Tang, Tao, Wei, Yanyu, Feng, Jinjun, and Gong, Yubin

Subjects

MAGNETIC coupling, ELECTRIC impedance, ELECTROMAGNETISM, ELECTRIC fields, MATHEMATICAL models

Abstract

In this paper, a 3-D fast time-domain nonlinear algorithm (FTDNA-3-D) based on particle-in-cell method for the beam–wave interaction of the sheet beam slow wave structure (SWS) is presented. Calculation equations of the circuit electric field and the space charge electric field are given. Calculation approaches of the energy exchange and the particle mover are displayed. A simplified coupling impedance simulation approach for sheet beam SWS is indicated. The FTDNA-3-D takes the transverse electric field and the focusing magnetic field into consideration. The FTDNA-3-D could reach a high simulation speed. This novel algorithm gives a faster accurate choice for the design of sheet beam traveling-wave tube (TWT). It could be used to enhance the design efficiency of sheet beam TWT. A Ka-band staggered double vane TWT is used to verify the FTDNA-3-D. Simulation results of output power and gain versus frequency from FTDNA-3-D are compared with results from CST particle studio. The results of FTDNA-3-D are in accord with CST particle studio well. [ABSTRACT FROM AUTHOR]

Published

2019

30. A numerical study for dielectric constant profile of aqueous solvent in ionic solution radiated by high-intensity electric pulses.

Author

Bo, Wenfei, Tang, Jingchao, Yang, Yang, Ma, Jialu, Huang, Qi, Guo, Lianghao, Wang, Zhanliang, Wu, Zhe, Zeng, Baoqing, and Gong, Yubin

Subjects

PERMITTIVITY, AQUEOUS solutions, HIGH intensity lasers

Abstract

In this paper, a mathematical physics model is set up to study dielectric constant profile of aqueous solvent in ionic solution, to revise Brownian dynamics simulation in ionic solution by considering time-variant dielectric constant profile with change in ion positions, and to study the effect of high-intensity electric pulses on the profile. The validation of the model is confirmed with verification calculations. By means of the proposed model, dielectric constant profiles in calcium chloride and sodium chloride solutions and their response to pulses are simulated. Based on numerical results, dielectric constants of aqueous solvent spatially vary instead of being the same value in ionic solutions. And the profiles are variant with time due to ion motion in solutions. From the profiles, overall dielectric constant in calcium chloride solution is lower than that in sodium chloride solution. And overall dielectric constant decreases with increment of solution concentration. In addition, the results show that influence on the profiles depends on solution concentration and field intensity of the pulse. The profile in solutions with low concentration is more vulnerable to the pulse than that with high concentration. And overall dielectric constant decreases dramatically as field intensity increases. Those understandings provide basis for application of pulses in biomedical engineering at the molecular level. Meanwhile, pulse radiation provides a potential way to constrain water molecules at room temperature reflected by significantly reducing dielectric constant, and to lower absorption loss of electromagnetic field in millimeter and far infrared band. [ABSTRACT FROM AUTHOR]

Published

2018

31. Third-Harmonic Traveling-Wave Tube Multiplier-Amplifier.

Author

Gong, Huarong, Wang, Qi, Deng, Difu, Meng, Xiang'ai, Dong, Yao, Xu, Jin, Tang, Tao, Su, Xiaogang, Wang, Zhanliang, Gong, Yubin, and Travish, Gil

Subjects

TRAVELING-wave tubes, ELECTRONIC amplifiers, ELECTRON beams, ELECTRONIC modulation, MILLIMETER waves

Abstract

A high-harmonic traveling-wave tube (HHTWT) is designed, developed, and tested in this paper. This device is configured as a multiplier–amplifier with Q-band input signals and its third harmonic, i.e., D-band output power. The tested result demonstrates that 280 mW at 133.5 GHz is obtained as a result of 200 mW at 44.5-GHz input signal. The simulation and experiment validate that the high-harmonic radiation can be generated and amplified in the HHTWT. The approach described in this paper could find application in exploring high power, wideband tunable terahertz source. This paper is expanded from a conference paper on IVEC 2017. The detail design produce and tested result are added in this paper. The explanation of the simulation and tested results is also presented. [ABSTRACT FROM AUTHOR]

Published

2018

32. Study on Radial Sheet Beam Electron Optical System for Miniature Low-Voltage Traveling-Wave Tube.

Author

Li, Xinyi, Wang, Zhanliang, He, Tenglong, Gong, Huarong, Duan, Zhaoyun, Wei, Yanyu, and Gong, Yubin

Subjects

*ELECTRON beams, *ELECTRODES, *MICROSTRIP transmission lines, *BEAM optics, *PARTICLE beams, *LOW voltage systems

Abstract

Angle log-periodic meander line microstrip radial sheet beam traveling-wave tube is one kind of novel minimized vacuum device with low beam voltage. To generate and focus the radial sheet electron beam, a novel radial divergent sheet beam electron optical system, including the tractable radial sheet electron beam gun and miniaturized and feasible radial small tunable periodic cusped magnetic focusing system, is proposed in this paper. The fan-shaped radial sheet beam is emitted from the cylindrical surface cathode, compressed in axial direction, and confined in azimuthal direction by the focusing electrode. Simulation results show that the total emission of the angular radial sheet beam gun is 51.2 mA with the dimensions of 0.26~\text mm \times 8 ° under the voltage of 1.7 kV, and the fan-shaped radial sheet beam can totally pass through the fan-shaped drift tunnel under the magnetic field. The experimental results are good in agreement with the simulation results. The tested angular radial sheet beam transmission efficiency is >90% in an 18.8-mm-length beam tunnel with the fill factor of 50%. [ABSTRACT FROM PUBLISHER]

Published

2017

33. Study of the Symmetrical Microstrip Angular Log-Periodic Meander-Line Traveling-Wave Tube.

Author

Wang, Shaomeng, Gong, Yubin, Wang, Zhanliang, Wei, Yanyu, Duan, Zhaoyun, and Feng, Jinjun

Subjects

TRAVELING-wave tubes, MAGNETIC coupling, ELECTRON beams, MICROSTRIP transmission lines, DISPERSION (Chemistry)

Abstract

The symmetrical microstrip angular log-periodic meander-line (ALPML) slow-wave structure (SWS), which is suitable for Ka-band low-voltage traveling-wave tubes, is described in this paper. The dispersion characteristics and coupling impendence of this kind of SWS are achieved by simulation. A radial uniform magnetic field of 0.4 T is developed using radially magnetized permanent magnets to focus the radial sheet electron beam. To exploit the potentialities of the symmetrical ALPML SWS, the beam–wave interaction is carried out with a radial convergent and a divergent sheet electron beam. For the radial divergent electron beam with a voltage of 791 V and a current of 0.3 A, an output power over 60 W with an electron efficiency of 26% at 30 GHz is achieved from particle-in-cell simulation. The effects of misalignments and phase mismatches are carried out at the end. [ABSTRACT FROM AUTHOR]

Published

2016

34. A High-Power Single Rectangular Grating Sheet Electron Beam Traveling-Wave Tube.

Author

Zhang, Yabin, Wang, Zhanliang, Zhou, Qing, Liu, Shuaihong, Bo, Wenfei, Li, Xinyi, Wang, Yanshuai, Tang, Xianfeng, Gong, Huarong, Duan, Zhaoyun, Wei, Yanyu, Feng, Jinjun, and Gong, Yubin

Subjects

*ELECTRON beams, *DIFFRACTION gratings, *TRAVELING-wave tubes, *OSCILLATIONS, *WAVEGUIDES, *CATHODE rays

Abstract

In this paper, a high-power Ka-band traveling-wave tube (TWT) driven by a sheet electron beam is proposed and demonstrated by means of the simulation and experimental methods. The single grating rectangular waveguide with large width-to-height ratio is used as the slow-wave structure (SWS). An $E$ -plane bend energy coupler is put forward to feed this wide SWS. An irregular transition structure between the input waveguide and the SWS is suggested and designed, which is beneficial to suppress the self-excited oscillation. For a practical electron beam (20 mm $\times \,\, 1$ mm, 150.1 kV, 850 A, and 20-ns), the output power of this single rectangular grating sheet beam TWT is larger than 750 kW from 34.5 to 35.4 GHz. The maximum power is 1.21 MW at 35 GHz, corresponding to a gain of 20.4 dB. [ABSTRACT FROM PUBLISHER]

Published

2016

35. Sheet Electron Beam Transport in a Metamaterial-Loaded Waveguide Under the Uniform Magnetic Focusing.

Author

Tang, Xianfeng, Duan, Zhaoyun, Shi, Xianbao, Zhang, Yabin, Wang, Zhanliang, Gong, Yubin, and Feng, Jinjun

Subjects

ELECTRON beams, METAMATERIALS, WAVEGUIDES, MAGNETIC fields, BOUNDARY value problems, COMPUTER simulation

Abstract

We have theoretically investigated the transport of a sheet electron beam focused by a uniform axial magnetic field in a metamaterial-loaded waveguide. A theoretical model has been proposed to analyze the sheet electron beam transport. In this model, we have used CST simulations to obtain the mean potential on the metamaterial as the boundary condition. According to the boundary condition, the space-charge electric field and the beam curling have been theoretically analyzed. It is found that the beam curling can be greatly reduced by decreasing the spacing between the metamaterial and the sheet electron beam. This model is verified using the CST simulations. This paper can pave the way for developing brand new metamaterial-based vacuum electron devices with a sheet electron beam. [ABSTRACT FROM AUTHOR]

Published

2016

36. Theoretical and Experimental Research on a Novel Small Tunable PCM System in Staggered Double Vane TWT.

Author

Shi, Xianbao, Wang, Zhanliang, Tang, Tao, Gong, Huarong, Wei, Yanyu, Duan, Zhaoyun, Tang, Xianfeng, Wang, Yuanyuan, Feng, Jinjun, and Gong, Yubin

Subjects

*MAGNETS, *LOW voltage systems, *ELECTRON beams, *MAGNETIC fields, *TRAVELING-wave tubes

Abstract

In this paper, a novel small tunable periodic cusped magnet (NSTPCM) system is proposed for the purpose of realizing low voltage, big current sheet electron beam propagation in a long distance in engineering, which is composed of a series of position-fixed magnet blocks in alignment and freely sliding staggered pole pieces. This kind of NSTPCM not only generates higher magnetic field in the axial direction but also realizes more convenient adjustment of magnetic field in the transverse direction. This NSTPCM system has been successfully applied in a Ka-band sheet electron beam staggered double vane traveling wave tube. The tested sheet beam transmission efficiency is $>93$ % in a 112.7-mm-length slow-wave structure under the condition of beam voltage 24.3 kV and beam current 0.8 A. Moreover, the measured output power is $>75$ W in the range from 33 to 37.5 GHz, and the maximum output power is 128 W at 34 GHz. This paper provides the foundation for the development of sheet electron beam vacuum devices. [ABSTRACT FROM PUBLISHER]

Published

2015

37. Analysis and Simulation of a Multigap Sheet Beam Extended Interaction Relativistic Klystron Amplifier.

Author

Zhao, Yucong, Li, Shifeng, Huang, Hua, Liu, Zhenbang, Wang, Zhanliang, Duan, Zhaoyun, Li, Xinyi, Wei, Yanyu, and Gong, Yubin

Subjects

BANDWIDTHS, KLYSTRONS, RELATIVITY, ELECTRIC admittance, ELECTRIC admittance measurement

Abstract

To improve the output power and electron efficiency and broaden the operating bandwidth, the three-gap extended output cavity was used in the relativistic klystron to replace the single-gap output cavity. The high-frequency characteristics of the three-gap extended cavity were studied. The electron load conductance was derived and corrected based on the theory of relativity, by which a more accurate relation of electron load conductance versus transmit angle can be obtained. The characteristic impedance is three times bigger than that of the single-gap cavity under the case of the $2\pi $ mode, which can improve the M^{2}(R/Q) and the beam–wave interaction efficiency. The model of sheet beam klystron (SBK) is comprised of three-gap input cavity, two-gap first idler, three-gap second idler cavity, and three-gap output cavity. The 3-D particle-in-cell simulation results show that for a 500 kV, 1 kA, 40.134 GHz, and 20 W input power, the SBK is capable of generating an output power higher than 142 MW with the gain of 68.5 dB, maximum interaction efficiency of 28.4%, and 3-dB bandwidth of 240 MHz. [ABSTRACT FROM PUBLISHER]

Published

2015

38. Study on Wideband Sheet Beam Traveling Wave Tube Based on Staggered Double Vane Slow Wave Structure.

Author

Shi, Xianbao, Wang, Zhanliang, Tang, Xianfeng, Tang, Tao, Gong, Huarong, Zhou, Qing, Bo, Wenfei, Zhang, Yabin, Duan, Zhaoyun, Wei, Yanyu, Gong, Yubin, and Feng, Jinjun

Subjects

*TRAVELING-wave tubes, *SLOW wave structures, *ELECTRON gun, *ELECTRON beam research, *BACKWARD wave oscillators

Abstract

In this paper, a wideband 220-GHz sheet-beam traveling-wave tube (TWT) based on staggered double vane slow-wave structure (SWS) is investigated. A novel method of loading the attenuator into the SWS for suppressing backward wave oscillation is proposed. In addition, a novel focusing electrode of the sheet beam gun is carried out in this paper, which is a whole structure but divided into two parts artificially, one is used to compress the electron beam in $X$ -direction and the other is used to compress the electron beam in $Y$ -direction. In addition, a novel anode is redesigned to reduce the defocusing effect caused by the equipotential surfaces. A nonuniform periodically cusped magnet is used for focusing the sheet electron beam, which is predicted to exhibit 100% beam transmission efficiency in a 75-mm length drift tube. The high-frequency characteristics of the SWS and the beam-wave interaction are also studied. The results reveal that the designed TWT is expected to generate over 78.125-W average power at 214 GHz, and the 3-dB bandwidth is 31.5 GHz, ranging from 203 to 234.5 GHz. [ABSTRACT FROM PUBLISHER]

Published

2014

39. Study of Low- Voltage Radial Convergent Sheet Electron Optical System.

Author

Wang, Shaomeng, Gong, Yubin, Wang, Zhanliang, Wei, Yanyu, Duan, Zhaoyun, Feng, Jinjun, and Liu, Qingxiang

Subjects

ELECTRON beam research, ELECTRON gun, ELECTRON optics, ELECTRONICS, MAGNETIC fields

Abstract

A new kind of radial convergent sheet beam electron optical system, which can be used in low voltage Ka-band radial electron devices, is studied in this paper, including the beam production, transmission, and focus. A novel radial high perveance electron gun is proposed, and its volt-ampere characteristics are obtained by means of simulation. The focusing system using permanent magnet rings is put forward, by which a radial uniform magnetic field can be obtained. With the electron gun and focusing system, a 1600 V, 8 A, and 0.04-mm thickness radial convergent sheet beam was produced, and the simulation result shown that it can pass through a 16-mm \(\times 0.06\) -mm radial channel 100%. [ABSTRACT FROM PUBLISHER]

Published

2014

40. Study of High-Power Ka-Band Rectangular Double-Grating Sheet Beam BWO.

Author

Zhang, Yabin, Gong, Yubin, Wang, Zhanliang, Liu, Shuaihong, Wei, Yanyu, Duan, Zhaoyun, Shi, Xianbao, Wang, Yanshuai, Zhang, Luqi, Zhou, Qing, and Liao, Junpeng

Subjects

ELECTRON beams, SLOW wave structures, WAVEGUIDES, MICROWAVE oscillators, RADIATION

Abstract

It is attractive to use sheet beam vacuum devices to generate high frequency, high-power microwave radiation. In this paper, we present the numerical and experimental studies of a high-power Ka-band sheet electron beam backward wave oscillator (BWO), in which the double-grating rectangular waveguide is used as the slow wave structure (SWS) for its thermal and mechanical robustness. The fundamental mode of this kind of SWS is an antisymmetric mode which has an antisymmetric longitudinal field distribution and will nonsynchronously interact with the electron beam on two sides of the electron channel along the vertical direction. We put forward a method to overcome this trouble in this paper. To drive this BWO, a high-power sheet beam is used with a cross section of 30 mm $\times\,$ 1 mm. A thin graphite cathode is used for its superiority in producing a high current, high-quality electron beam. For an experimental electron beam of 141 kV and 1668 A, the output power of over 46.8 MW at 31.68 GHz is obtained, which corresponds to a beam–wave interaction efficiency of 19.9%. Compared with the conventional hollow beam BWO and the single-grating rectangular waveguide sheet beam BWO, the double-grating sheet beam BWOs efficiency is higher, which indicates that the double-grating sheet beam device is promising for producing millimeter wave radiation with high power and high efficiency. [ABSTRACT FROM PUBLISHER]

Published

2014

41. Study of a Log-Periodic Slow Wave Structure for Ka-band Radial Sheet Beam Traveling Wave Tube.

Author

Wang, Shaomeng, Gong, Yubin, Hou, Yan, Wang, Zhanliang, Wei, Yanyu, Duan, Zhaoyun, and Cai, Jun

Subjects

DIGITAL communications, BROADBAND communication systems, PARTICLES (Nuclear physics), DATA transmission systems, NUCLEAR physics

Abstract

A novel slow wave structure (SWS) named angular log-periodic meander-line is proposed for a radial traveling wave tube (TWT). In this paper, a 30 log-periods microstrip angular log-periodic meander-line SWS is studied. The dispersion of this kind of SWS is weak, which shows that it can work in a wide operating bandwidth. The more important advantage is that the operating voltage is much lower than that of the conventional TWT at the same operating frequency and the geometrical dimension is also much smaller than that of the conventional TWT. The beam–wave interaction of the angular log-periodic meander-line TWT is calculated using the particle-in-cell method. When the operating voltage is 1624 V, this kind of TWT can give 156.5-W output power at 35 GHz, the gain is 21.9 dB, and the electron efficiency is \sim17.7\%. With this kind of TWT as mentioned, the concept of radial integrated angular log-periodic meander-line TWT is proposed, which can provide a new way to obtain higher output power. [ABSTRACT FROM PUBLISHER]

Published

2013

42. A 340 GHz High-Power Multi-Beam Overmoded Flat-Roofed Sine Waveguide Traveling Wave Tube.

Author

Luo, Jinjing, Xu, Jin, Yin, Pengcheng, Yang, Ruichao, Yue, Lingna, Wang, Zhanliang, Xu, Lin, Feng, Jinjun, Liu, Wenxin, and Wei, Yanyu

Subjects

TRAVELING-wave tubes, SLOW wave structures, SIMULATION software

Abstract

A phase shift that is caused by the machining errors of independent circuits would greatly affect the efficiency of the power combination in traditional multi-beam structures. In this paper, to reduce the influence of the phase shift and improve the output power, a multi-beam shunted coupling sine waveguide slow wave structure (MBSC-SWG-SWS) has been proposed, and a multi-beam overmoded flat-roofed SWG traveling wave tube (TWT) based on the MBSC-SWG-SWS was designed and analyzed. A TE10-TE30 mode convertor was designed as the input/output coupler in this TWT. The results of the 3D particle-in-cell (PIC) simulation with CST software show that more than a 50 W output power can be produced at 342 GHz, and the 3 dB bandwidth is about 13 GHz. Furthermore, the comparison between the single-beam sine waveguide (SWG) TWT and the multi-beam overmoded SWG TWT indicates that the saturated output power of the multi-beam overmoded SWG TWT is three times more than that of the single beam SWG TWT. [ABSTRACT FROM AUTHOR]

Published

2021

43. High-Power Millimeter-Wave BWO Driven by Sheet Electron Beam.

Author

Wang, Zhanliang, Gong, Yubin, Wei, Yanyu, Duan, Zhaoyun, Zhang, Yabin, Yue, Linna, Gong, Huarong, Yin, Hairong, Lu, Zhigang, Xu, Jin, and Feng, Jinjun

Subjects

*MILLIMETER waves, *RECTANGULAR waveguides, *ELECTRON beams, *CROSS-sectional method, *RADIATION sources

Abstract

The sheet beam vacuum electron device is an attractive choice for generating high-power high-frequency microwave radiation. A millimeter-wave sheet beam backward wave oscillator (BWO) is presented in this paper. The rectangular waveguide grating structure is used as its slow wave structure. The BWO is driven by a sheet beam with a cross-sectional area of 30 mm \times 1 mm which is generated by a thin cathode. For a beam voltage of 167 kV and a beam current of 1.4 kA, the output power is 40 MW at 36.6 GHz. The beam–wave interaction efficiency is about 17%, which is higher than that of conventional hollow beam BWO. It is clear from the results presented in this paper that the sheet beam device is promising for producing high-efficiency high-power millimeter-wave radiation. [ABSTRACT FROM AUTHOR]

Published

2013

44. Crystal growth and magnetic property of YFeO crystal.

Author

WU, ANHUA, SHEN, HUI, XU, JUN, WANG, ZHANLIANG, JIANG, LINWEN, LUO, LIQING, YUAN, SHUJUAN, CAO, SHIXUN, and ZHANG, HUAIJIN

Subjects

CRYSTAL growth, MAGNETIC properties, RARE earth metal alloys, ANISOTROPY, DETECTORS, OPTICAL properties

Abstract

YFeO $_{\boldsymbol 3}$ and other rare earth substituted crystals with distorted orthorhombic pervoskite-like structure (space group, Pbnm) have attracted much attention due to their remarkable magnetic properties of primary significance for technological applications. In the present work, the floating zone growth of YFeO $_{\boldsymbol 3}$ crystals has been systematically investigated and high quality YFeO $_{\boldsymbol 3}$ crystal was obtained by optimized process. The magnetic properties of YFeO $_{\boldsymbol 3}$ crystal were investigated, and it indicated the high magneto-optical property in YFeO $_{\boldsymbol 3}$ crystals with specific orientation due to its anisotropy. YFeO $_{\boldsymbol 3}$ crystals display superior performance in the application magneto-optical current sensors and fast latching optical switches. [ABSTRACT FROM AUTHOR]

Published

2012

45. Study of an Attenuator Supporting Meander-Line Slow Wave Structure for Ka-Band TWT.

Author

Wang, Hexin, Wang, Shaomeng, Wang, Zhanliang, Li, Xinyi, He, Tenglong, Xu, Duo, Duan, Zhaoyun, Lu, Zhigang, Gong, Huarong, and Gong, Yubin

Subjects

SLOW wave structures, TRAVELING-wave tubes, SURFACE roughness, COPPER films, MAGNETRON sputtering, LASER beam cutting, ELECTRON beams

Abstract

An attenuator supporting meander-line (ASML) slow wave structure (SWS) is proposed for a Ka-band traveling wave tube (TWT) and studied by simulations and experiments. The ASML SWS simplifies the fabrication and assembly process of traditional planar metal meander-lines (MLs) structures, by employing an attenuator to support the ML on the bottom of the enclosure rather than welding them together on the sides. To reduce the surface roughness of the molybdenum ML caused by laser cutting, the ML is coated by a thin copper film by magnetron sputtering. The measured S11 of the ML is below −20 dB and S21 varies around −8 dB to −12 dB without the attenuator, while below −40 dB with the attenuator. Particle-in-cell (PIC) simulation results show that with a 4.4-kV, 200-mA sheet electron beam, a maximum output power of 126 W is obtained at 38 GHz, corresponding to a gain of 24.1 dB and an electronic efficiency of 14.3%, respectively. [ABSTRACT FROM AUTHOR]

Published

2021

46. Designing a Water-Immersed Rectangular Horn Antenna for Generating Underwater OAM Waves.

Author

Yang, Yang, Wang, Zhanliang, Wang, Shaomeng, Zhou, Qing, Shen, Fei, Jiang, Haibo, Wu, Zhe, Zeng, Baoqing, Guo, Zhongyi, and Gong, Yubin

Subjects

HORN antennas, ANTENNA arrays, ANTENNA feeds, DIELECTRIC resonator antennas, COAXIAL cables, WAVEGUIDE antennas

Abstract

In order to extend the applications of vortex waves, we propose a water-immersed rectangular horn antenna array for generating underwater vortex waves carrying the orbital angular momentum (OAM). Firstly, a single dielectric-loaded rectangular horn antenna with the central frequency of 2.6 GHz was designed for generating underwater electromagnetic (EM) waves. Due to the supplementing dielectric-loaded waveguide in this single antenna, the problems with difficult sealing and fixation of the feed probe could be solved effectively. The simulation results show that it has a good impedance characteristics (S11 < −10 dB) and reasonable losses (less than 3.5 dB total for two antennas and a coaxial line) from 2.5 GHz to 2.7 GHz. Experiments on the single antenna were also carried out, which agree well with the simulations. Based on the designed single antenna, the water-immersed rectangular horn antenna array was proposed, and the phase gradient from 0~2π was fed to the horn antennas for generating underwater OAM waves. The simulation results demonstrate high fidelity of the generated OAM waves from the intensity and phase distributions. The purity of the generated OAM modes was also investigated and further verifies the high fidelity of the generated OAM waves. The generated high-quality OAM waves meet the requirements for underwater applications of OAM, such as underwater communication and underwater imaging. [ABSTRACT FROM AUTHOR]

Published

2019

47. Observation of the reversed Cherenkov radiation.

Author

Duan, Zhaoyun, Tang, Xianfeng, Wang, Zhanliang, Zhang, Yabin, Chen, Xiaodong, Chen, Min, and Gong, Yubin

Abstract

Reversed Cherenkov radiation is the exotic electromagnetic radiation that is emitted in the opposite direction of moving charged particles in a left-handed material. Reversed Cherenkov radiation has not previously been observed, mainly due to the absence of both suitable all-metal left-handed materials for beam transport and suitable couplers for extracting the reversed Cherenkov radiation signal. In this paper, we develop an all-metal metamaterial, consisting of a square waveguide loaded with complementary electric split ring resonators. We demonstrate that this metamaterial exhibits a left-handed behaviour, and we directly observe the Cherenkov radiation emitted predominantly near the opposite direction to the movement of a single sheet electron beam bunch in the experiment. These observations confirm the reversed behaviour of Cherenkov radiation. The reversed Cherenkov radiation has many possible applications, such as novel vacuum electronic devices, particle detectors, accelerators and new types of plasmonic couplers. [ABSTRACT FROM AUTHOR]

Published

2017