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18 results on '"Wang, Shaozhi"'

1. Organic covalent modification to improve thermoelectric properties of TaS2.

Author

Wang, Shaozhi, Yang, Xiao, Hou, Lingxiang, Cui, Xueping, Zheng, Xinghua, and Zheng, Jian

Abstract

Organic semiconductors are attracting considerable attention as a new thermoelectric material because of their molecular diversity, non-toxicity and easy processing. The side chains which are introduced into two-dimensional (2D) transition metal dichalcogenides (TMDs) by covalent modification lead to a significant decrease in their thermal conductivity. Here, we describe a simple approach to preparing the side chains covalent modification TaS2 (SCCM-TaS2) organic/inorganic hybrid structures, which is a homogeneous and non-destructive technique that does not depend on defects and boundaries. Electrical conductivity of 3,401 S cm-1 and a power factor of 0.34 mW m-1 K-2 are obtained for a hybrid material of SCCM-TaS2, with an in-plane thermal conductivity of 4.0 W m-1 K-1, which is 7 times smaller than the thermal conductivity of the pristine TaS2 crystal. The power factor and low thermal conductivity contribute to a thermoelectric figure of merit (ZT) of ~0.04 at 443 K.

Published
2022

3. A Dual-polarized Frequency Selective Rasorber with a Tunable Transparent Band.

Author

SHI Tongtong, ZHANG Xiaofa, WU Weiwei, WANG Shaozhi, XU Yixuan, YAN Yuchen, and YAN Xiao

Subjects
ELECTROMAGNETIC wave absorption, VARACTORS, INSERTION loss (Telecommunication), RADOMES, VOLTAGE
Abstract

Copyright of Telecommunication Engineering is the property of Telecommunication Engineering and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2024
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4. Design of miniaturized and highly selective frequency selective rasorber based on compact spiral resonator.

Author

Xu, Yixuan, Wu, Weiwei, Shi, Qingzhan, Shi, Tongtong, and Wang, Shaozhi

Abstract

A miniaturized, high‐selectivity, wideband A‐T‐A frequency selective rasorber (FSR) based on compact spiral resonators (CSR) is proposed here. The lossy layer of the FSR consists of the CSR and a Jerusalem cross, with four resistors soldered onto the surface. The underlying layer is a bandpass frequency selective surface (FSS) with an extremely narrow slit. The dimensions of the FSR unit are only 0.079 λL × 0.079 λL × 0.078 λL. The extremely narrow‐slitted FSS and CSR together provide a narrowband frequency response, enhancing the selectivity of the FSR. Additionally, a prototype of an FSR was fabricated and tested, achieving results highly consistent with simulations. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Broadband RCS Reduction Metasurface With a Reconfigurable High-Selectivity Transmission Band

Author

Ma, Yuhong, Wu, Weiwei, Yan, Yuchen, Wang, Shaozhi, Yuan, Wentao, Huang, Jingjian, and Yuan, Naichang

Abstract

In this article, a broadband radar cross section (RCS) reduction metasurface with a reconfigurable high-selectivity passband is proposed. Based on the equivalent circuit analysis, the feasibility of achieving the high-selective passband with multimode working state and RCS reduction near the passband through the combination of the checkerboard metasurface and the switchable bandpass frequency selective structure (FSS) is verified. The switchable FSS in the bottom layer can realize the function of wave transmittance/reflection by controlling the ON/OFF states of the p-i-n-diodes, and a novel staggered patch structure is introduced to realize the fast conversion between different working modes without using complex feeding networks. The checkerboard metasurface in the upper layer not only realizes the RCS reduction function through scattering cancellation but also improves the passband selectivity of the switchable FSS under different working modes. Finally, a prototype of the proposed structure is fabricated and measured. The measured results show that the proposed structure can be flexibly switched between the three working modes. In different working modes, the structure has a wide RCS reduction bandwidth and a high-selective passband.

Published
2024
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6. Monolayer single crystal two-dimensional quantum dots viaultrathin cutting and exfoliating

Author

Hao, Yang, Su, Wen, Hou, Lingxiang, Cui, Xueping, Wang, Shaozhi, Zhan, Pengxin, Zou, Ye, Fan, Louzhen, and Zheng, Jian

Abstract

Two-dimensional (2D) atomically thin quantum dots (QDs) possess extraordinary electrical and optical properties. However, fabricating high quality 2D QDs viaa universal and reliable technique remains a challenge. Here, we report a simple strategy to prepare high quality, monolayer single crystal 2D QDs viaultrathin cutting 2D bulk single crystals by ultramicrotome, followed by an exfoliation process. The as-prepared 2D QDs have pristine surface, high quality, high monolayer yield and high photoluminescence quantum yield (the highest photoluminescence quantum yield of WS2is 18%), which can be used as promising, low toxic, biocompatible, and good cell-permeability fluorescent labeling agents for in vitroimaging.

Published
2024
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8. An Ultrathin Low-Profile Tightly Coupled Dipole Array Fed by Compact Zigzagging Baluns.

Author

Wu, Weiwei, Yan, Yuchen, Wang, Shaozhi, Ma, Yuhong, and Yuan, Naichang

Subjects
BALUNS, ANTENNA feeds, IMPEDANCE matching, PHASED array antennas, MICROSTRIP transmission lines
Abstract

In this paper, we propose for the first time a novel feed approach to a tightly coupled dipole array (TCDA). Firstly, compact zigzagging microstrip feedlines are utilized as baluns to feed our array elements to obtain wideband impedance-matching characteristics. Secondly, this array is designed on ultrathin substrates aiming at obtaining ultra-tight coupling between the dipole arms of two neighboring elements. Some irreplaceable parasitic pads are developed and added to the radiating arms to improve both the impedance and radiation characteristics of the TCDA. With these technologies, a 12 × 12 TCDA prototype is designed, fabricated and measured for verification. The array achieves an impressive impedance bandwidth spanning of 4–18 GHz for S 11 < − 10   dB . Its radiation patterns and realized gain are measured to verify its stable electromagnetic characteristics. Its realized gain is from 15 dB to 25 dB within the operating frequency band. Its efficiency is around 91%. Its measured results show good agreement with simulations. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Ultra‐wideband frequency selective surface based tightly coupled dipole array with integrated balun.

Author

Wang, Qingping, Ye, Yuan, Wang, Shaozhi, Zhang, Ximeng, and Yuan, Naichang

Subjects
FREQUENCY selective surfaces, ANTENNA arrays, IMPEDANCE matching, STANDING waves, PRINTED circuits
Abstract

An ultra‐wideband and wide‐scan tightly coupled dipoles array based on frequency selective surface (FSS) is proposed, and the traditional wide‐angle scan impedance matching dielectric layer is replaced by FSS with printed metal strips to achieve the tuning of the scanning impedance of the array. Additionally, the metal strip FSS, dipole radiating elements and feeding structure are all printed on the same printed circuit board, and the whole design is highly integrated. Finally, a low‐cost lightweight single‐polarization tightly coupled antenna array with ultra‐wide band and wide scan performance is presented. Subject to the criterion of active Voltage standing Wave ratio(VSWR) < 3, beam scanning coverage of ±45° along E plane, H plane and D plane can be accomplished within the frequency band range across 0.4–2 GHz. An array prototype was produced and tested, and the results showed that the effectiveness of the design was well validated. [ABSTRACT FROM AUTHOR]

Published
2023
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13. Organic covalent modification to improve thermoelectric properties of TaS2.

Author

Wang, Shaozhi, Yang, Xiao, Hou, Lingxiang, Cui, Xueping, Zheng, Xinghua, and Zheng, Jian

Subjects
THERMOELECTRIC materials, ORGANIC semiconductors, THERMAL conductivity, ELECTRIC conductivity, HYBRID materials, TRANSITION metals
Abstract

Organic semiconductors are attracting considerable attention as a new thermoelectric material because of their molecular diversity, non-toxicity and easy processing. The side chains which are introduced into two-dimensional (2D) transition metal dichalcogenides (TMDs) by covalent modification lead to a significant decrease in their thermal conductivity. Here, we describe a simple approach to preparing the side chains covalent modification TaS2 (SCCM-TaS2) organic/inorganic hybrid structures, which is a homogeneous and non-destructive technique that does not depend on defects and boundaries. Electrical conductivity of 3,401 S cm−1 and a power factor of 0.34 mW m−1 K−2 are obtained for a hybrid material of SCCM-TaS2, with an in-plane thermal conductivity of 4.0 W m−1 K−1, which is 7 times smaller than the thermal conductivity of the pristine TaS2 crystal. The power factor and low thermal conductivity contribute to a thermoelectric figure of merit (ZT) of ~0.04 at 443 K. The improvement of thermoelectric performance of materials by reducing lattice thermal conductivity is challenging. Here, the authors find the side chains covalent modification of transition metal disulfides reducing the lattice thermal conductivity. [ABSTRACT FROM AUTHOR]

Published
2022
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15. Thermal Rectifier and Thermal Transistor of 1T/2H MoS2for Heat Flow Management

Author

Yang, Xiao, Wang, Shaozhi, Wang, Chunyang, Lu, Rui, Zheng, Xinghua, Zhang, Ting, Liu, Ming, Zheng, Jian, and Chen, Haisheng

Abstract

Thermal rectifiers and thermal transistors are expected to be widely used for efficient thermal management and energy cascade utilization due to their excellent directional thermal management. Two-dimensional micro/nano materials have huge potential in the applications of thermal transistors, thermal logic circuits, and thermal rectifiers owing to the phase transition and thermal rectification phenomenon. Herein, a lithium intercalation method was used to transform 2H–MoS2into the 1T phase with a purity of 76%, and a suspended microelectrode was applied to measure the thermal conductivity and thermal rectification coefficient of the same MoS2film with 1T and 2H phases in suit. The thermal conductivity and thermal rectification effect of two-phase MoS2couple with its phase state and structure were also obtained. The results demonstrate that the thermal conductivities of MoS2in both 1T and 2H phases decrease with increasing temperature. It is also found that the thermal rectification coefficient has no obvious dependence on the temperature and phase change but the asymmetric structure. Furthermore, a thermal rectifier and transistor with a high thermal rectification effect are designed. The direction and magnitude of heat flow through the samples can be effectively controlled and managed by adjusting the phase, size, and structural asymmetry of the different samples. The maximum thermal rectification coefficient of the thermal rectifiers is up to 0.8.

Published
2022
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18. Thermal Rectifier and Thermal Transistor of 1T/2H MoS 2 for Heat Flow Management.

Author

Yang X, Wang S, Wang C, Lu R, Zheng X, Zhang T, Liu M, Zheng J, and Chen H

Abstract

Thermal rectifiers and thermal transistors are expected to be widely used for efficient thermal management and energy cascade utilization due to their excellent directional thermal management. Two-dimensional micro/nano materials have huge potential in the applications of thermal transistors, thermal logic circuits, and thermal rectifiers owing to the phase transition and thermal rectification phenomenon. Herein, a lithium intercalation method was used to transform 2H-MoS 2 into the 1T phase with a purity of 76%, and a suspended microelectrode was applied to measure the thermal conductivity and thermal rectification coefficient of the same MoS 2 film with 1T and 2H phases in suit. The thermal conductivity and thermal rectification effect of two-phase MoS 2 couple with its phase state and structure were also obtained. The results demonstrate that the thermal conductivities of MoS 2 in both 1T and 2H phases decrease with increasing temperature. It is also found that the thermal rectification coefficient has no obvious dependence on the temperature and phase change but the asymmetric structure. Furthermore, a thermal rectifier and transistor with a high thermal rectification effect are designed. The direction and magnitude of heat flow through the samples can be effectively controlled and managed by adjusting the phase, size, and structural asymmetry of the different samples. The maximum thermal rectification coefficient of the thermal rectifiers is up to 0.8.

Published
2022
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