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1. Racemic dielectric metasurfaces for arbitrary terahertz polarization rotation and wavefront manipulation

Author

Jie Li, Xueguang Lu, Hui Li, Chunyu Song, Qi Tan, Yu He, Jingyu Liu, Li Luo, Tingting Tang, Tingting Liu, Hang Xu, Shuyuan Xiao, Wanxia Huang, Yun Shen, Yan Zhang, Yating Zhang, and Jianquan Yao

Subjects
racemic, dielectric metasurfaces, terahertz waves, chirality, Optics. Light, QC350-467
Abstract

Dielectric chiral metasurface is a new type of planar and efficient chiral optical device that shows strong circular dichroism or optical activity, which has important application potential in optical sensing and display. However, the two types of chiral optical responses in conventional chiral metasurfaces are often interdependent, as their modulation of the amplitudes and phases of orthogonal circularly polarized components is correlated, which limits the further progress of chiral meta-devices. Here we propose a new scheme for independently designing the circular dichroism and optical activity of chiral metasurfaces to further control the polarization and wavefront of transmitted waves. Inspired by mixtures of chiral molecular isomers, we use the dielectric isomer resonators to form “super-units” instead of single meta-atoms for chiral responses in terahertz band, which is called racemic metasurface. By introducing two levels of Pancharatnam-Berry phases between meta-atoms and “super-units”, the polarization rotation angle and wavefront of the beam can be designed without the far-field circular dichroism. We demonstrate the strong control ability on terahertz waves of this scheme through simulation and experiments. In addition, this new type of device with near-field chirality but no far-field circular dichroism may also have important value in optical sensing and other technologies.

Published
2024
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2. A terahertz meta-sensor array for 2D strain mapping

Author

Xueguang Lu, Feilong Zhang, Liguo Zhu, Shan Peng, Jiazhen Yan, Qiwu Shi, Kefan Chen, Xue Chang, Hongfu Zhu, Cheng Zhang, Wanxia Huang, and Qiang Cheng

Subjects
Science
Abstract

Abstract Large-scale stretchable strain sensor arrays capable of mapping two-dimensional strain distributions have gained interest for applications as wearable devices and relating to the Internet of Things. However, existing strain sensor arrays are usually unable to achieve accurate directional recognition and experience a trade-off between high sensing resolution and large area detection. Here, based on classical Mie resonance, we report a flexible meta-sensor array that can detect the in-plane direction and magnitude of preloaded strains by referencing a dynamically transmitted terahertz (THz) signal. By building a one-to-one correspondence between the intrinsic electrical/magnetic dipole resonance frequency and the horizontal/perpendicular tension level, arbitrary strain information across the meta-sensor array is accurately detected and quantified using a THz scanning setup. Particularly, with a simple preparation process of micro template-assisted assembly, this meta-sensor array offers ultrahigh sensor density (~11.1 cm−2) and has been seamlessly extended to a record-breaking size (110 × 130 mm2), demonstrating its promise in real-life applications.

Published
2024
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3. Drone-TOOD: A Lightweight Task-Aligned Object Detection Algorithm for Vehicle Detection in UAV Images

Author

Kaitong Ou, Chaojun Dong, Xiankun Liu, Yikui Zhai, Ye Li, Wanxia Huang, Wenkang Qiu, Yizhi Wang, and Chengxuan Wang

Subjects
Vehicle detection, task align, real-time object detection, lightweight network, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Vehicle object detection using UAV images is a crucial undertaking in urban traffic management and the advancement of autonomous driving technologies. Conventional networks fail to achieve accuary in detecting vehicle objects from a drone’s perspective due to the significant variations in the size of the target items, unequal distribution of their positions in the image, and image degradation induced by the drone’s movement.In order to surmount this challenge, this research suggests an enhanced TOOD object detection model named Drone-TOOD. The first proposal is to create a lightweight network skeleton called CSPRegNet by merging CSPblock with Regblock. Secondly, we incorporate Regblock into CSPPAFPN to enhance CSPRegPAFPN and incorporate EVCblock at the upsampling location of deep features to capture corner area details and minimize the degradation of feature information. In addition, a efficient task decomposition attention module is also proposed to enhance the interaction ability of positioning and classification tasks. This task decomposition module can highlight the characteristics of a specific task while retaining the characteristics of another task, thereby improving detection capabilities. Experiments conducted on the Drone Vision Challenge Benchmark (VisDrone) demonstrate that the enhanced model can obtain superior performance compared to TOOD. The average precision (mAP) achieved by our approach is 64%, surpassing TOOD by 7.9%. The frames per second (FPS) stayed constant at 27.2. Drone-TOOD demonstrates superior performance compared to other lightweight models on the VisDrone-2021 dataset. In order to demonstrate the robustness of our approach, we additionally performed ablation experiments and conducted tests on the UAV Detection and Tracking Dataset (UAVDT), resulting in an achieved mean average precision (mAP) of 64.6%. Furthermore, Drone-TOOD possesses a total of parameter approximately 21.7 M.

Published
2024
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4. Scattering characteristics of silicon nanoprisms: A theoretical investigation across monomeric to hexameric structures

Author

Yong Zhou, Yujie Meng, Wuying Huang, Kuanguo Li, Zhenwei Wang, and Wanxia Huang

Subjects
Physics, QC1-999
Abstract

Dielectric nanostructures exhibit intriguing optical properties and outstanding advantages in designing optical nanoantennas and metasurfaces compared to plasmonic nanostructures. This study employs classical electrodynamic methods to comprehensively explore the scattering characteristics of silicon triangular nanoprisms in monomer and oligomer forms. For monomeric nanoprisms, the scattering spectra reveal two distinct and prominent resonance peaks attributed to magnetic dipole (MD) and electric dipole (ED) modes. Reducing interparticle gaps within dimeric structures leads to noticeable blueshifts in MD resonance peaks with stable intensities, in contrast to the nearly constant position and significantly reduced intensities of the ED resonance peaks. A pronounced Fano-like resonance was observed upon transitioning to tetrameric and hexameric configurations, resulting from the coupling between MD and ED modes. A broad resonance peak also emerges in the long-wavelength region due to MD-to-MD coupling. The simulations conducted herein hold significant theoretical implications, advancing our comprehension of the scattering properties of dielectric nanoparticles and contributing valuable insights into fundamental nanophotonics.

Published
2024
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5. Nanoprisms in plasmonic sensing: A comprehensive analysis of geometric effects

Author

Yong Zhou, Jiahui Zhu, Wuying Huang, Zhenwei Wang, Kuanguo Li, and Wanxia Huang

Subjects
Surface plasmon, Nanoprism, Sensing performance, Geometric effect, Physics, QC1-999
Abstract

The highly sensitive and versatile technique of plasmonic sensing has been widely employed in detecting and analyzing chemical or biological substances. This work employs classical electrodynamics methods to investigate the sensing performance of nanoprisms systematically. By varying heights, base edge lengths, and rounding radii of base corners of triangular nanoprism, we explore their influence on sensitivity and the figure of merit (FOM) in both transverse and longitudinal polarization cases. Our findings indicate that enlarged triangular prisms exhibit enhanced sensitivity, but a decrease in FOM counterbalances this improvement. Conversely, reducing the rounding radius of the base corners of the triangular prism leads to simultaneous improvements in sensitivity and FOM. We suggest prioritizing triangular or tetrahedral prisms in fabricating nanosensors for higher FOM or sensitivity, respectively. These insights provide valuable directions for designing and optimizing plasmonic sensors in practical usage.

Published
2024
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6. Deep-learning-based ring artifact correction for tomographic reconstruction

Author

Tianyu Fu, Yan Wang, Kai Zhang, Jin Zhang, Shanfeng Wang, Wanxia Huang, Yaling Wang, Chunxia Yao, Chenpeng Zhou, and Qingxi Yuan

Subjects
ring artifact correction, x-ray tomography, deep learning, residual neural network, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798, Crystallography, QD901-999
Abstract

X-ray tomography has been widely used in various research fields thanks to its capability of observing 3D structures with high resolution non-destructively. However, due to the nonlinearity and inconsistency of detector pixels, ring artifacts usually appear in tomographic reconstruction, which may compromise image quality and cause nonuniform bias. This study proposes a new ring artifact correction method based on the residual neural network (ResNet) for X-ray tomography. The artifact correction network uses complementary information of each wavelet coefficient and a residual mechanism of the residual block to obtain high-precision artifacts through low operation costs. In addition, a regularization term is used to accurately extract stripe artifacts in sinograms, so that the network can better preserve image details while accurately separating artifacts. When applied to simulation and experimental data, the proposed method shows a good suppression of ring artifacts. To solve the problem of insufficient training data, ResNet is trained through the transfer learning strategy, which brings advantages of robustness, versatility and low computing cost.

Published
2023
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7. A novel design of 3D carbon host for stable lithium metal anode

Author

Hang Liu, Jie Di, Ping Wang, Rui Gao, Han Tian, Pengfei Ren, Qingxi Yuan, Wanxia Huang, Ruiping Liu, Qiang Liu, and Ming Feng

Subjects
3D conductive hosts, anodes, carbon, Li dendrites, lithium metal batteries, Production of electric energy or power. Powerplants. Central stations, TK1001-1841
Abstract

Abstract Rational design of porous conductive hosts with high electrical conductivity, large surface area, and adequate interior space is desirable to suppressing dendritic lithium growth and accommodating large volume change of lithium metal anode during the Li plating/stripping process. However, due to the conductive nature of the conductive hosts, Li is easily deposited directly on the top of the hosts, which hinders it from fully functioning. To circumvent the issue, in this study, we designed a novel porous carbon host with a gradient‐pore‐size structure based on one‐dimensional (1D) carbon with different diameters. With this kind of host, stable cycling with high and stable Coulombic efficiency of ~98% is achieved at 0.5 mA cm−2 with an areal capacity of 1 mAh cm−2 over 320 cycles. In contrast, the normal three‐dimensional (3D) carbon nanotube host presents a moss‐like Li morphology with wildly fluctuating Coulombic efficiency after 100 cycles. The results reveal that the unique gradient‐pore‐size structure of the 3D conductive host greatly improves the performance of lithium metal batteries.

Published
2022
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8. Application scope of multipole method for decomposition of plasmonic spectrum

Author

Yong Zhou, Yujie Meng, Wanxia Huang, and Kuanguo Li

Subjects
Localized surface plasmon, Electromagnetic multipole, Quasi-normal mode, Physics, QC1-999
Abstract

The electromagnetic multipole method has been extensively adopted for a better understanding of the physical mechanism of localized surface plasmon. In this work, we quantitatively decomposed the total extinction spectra of typical silver nanoparticles into multipole components, which are shown to be quite different from qualitative assignment of resonance peaks reported previously. Taking the quasi-normal mode method as reference standard, we examined the scope of application of the electromagnetic multipole method in assigning plasmonic resonance peaks, and pointed out the necessity of employing eigenmode-based approaches when interpreting plasmonic spectra, which can hopefully lead to more physical insights into the underlying mechanisms of plasmonics phenomena.

Published
2022
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9. High-performance 3D biphasic NH4V3O8/Zn3(OH)2V2O7·2H2O synthesized by rapid chemical precipitation as cathodes for Zn-ion batteries

Author

Liu Liu, Zifeng Lin, Qiwu Shi, Jibin Tang, Zhichao Li, Zhijian Tao, and Wanxia Huang

Subjects
Aqueous Zn-ion batteries, Biphasic vanadate, Rapid chemical precipitation synthesis, 3D skeleton structure, Industrial electrochemistry, TP250-261, Chemistry, QD1-999
Abstract

Vanadate with layered structures and large open frameworks has been extensively explored as cathodes materials for aqueous Zn-ion batteries (ZIBs), and superior Zn-ion storage performance have been achieved. The biphasic vanadate materials are investigated to be conducive for further performance improvement. However, the lack of rapid and scalable synthesis strategies poses stiff challenges for the wider industrial economy of vanadate. Herein, the 3D biphasic NH4V3O8/Zn3(OH)2V2O7·2H2O (NVO/ZVO) were obtained via rapid microwave irradiation assisted chemical precipitation. The prepared electrode by NVO/ZVO with multiple nanoflower-structures presents a high specific capacity (332 mAh g−1 at 0.1 A g−1), together with exceedingly good energy density (281 Wh kg−1) and power density (94 W kg−1). Moreover, it can maintain a specific capacity of 92 % (132 mAh g−1) after 1000 cycles at a high current density of 10 A g−1. The high electrochemical performance of the cathode can be ascribed to the energy storage mechanism of dual-ion intercalation. This work provides key insights into the rapid synthesis of high-performance biphasic vanadate cathode materials for advanced ZIBs.

Published
2022
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10. Microstructure and Wear Resistance of Ti5Si3/Ti3Al Composite Coatings Prepared by Laser Cladding on TA2 Titanium Alloy

Author

Kaijin Huang and Wanxia Huang

Subjects
laser cladding, Ti5Si3/Ti3Al composite coatings, wear resistance, TA2 titanium alloy, Science
Abstract

In order to improve the wear resistance of titanium alloy, a Ti5Si3/Ti3Al composite coating with improved wear resistance was successfully prepared by laser cladding TA2 titanium alloy using the double-layer presetting method of Ti-63 wt.% Al mixed powder layer/Si powder layer. The microstructure, phase composition and wear resistance of the coating were studied using X-ray diffraction (XRD), scanning electron microscopy (SEM) and pin-disk friction and wear method. The results show that the coating is mainly composed of the Ti5Si3 primary phase and Ti5Si3/Ti3Al eutectic structure. The microhardness of the coating is higher than that of the matrix. The average microhardness of the coating is about 668 HV0.1, which is 3.34 times that of the matrix. The coating significantly improves the wear resistance of the TA2 matrix, and the mass wear rate is 1/5.79 of that of the TA2 matrix. The main wear mechanisms of the coating are abrasive wear, adhesive wear and oxidative wear, whereas the main wear mechanisms of the TA2 matrix are adhesive wear and oxidative wear.

Published
2023
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11. Transcriptome profiling of cells exposed to particular and intense electromagnetic radiation emitted by the 'SG-III' prototype laser facility

Author

Jiangbin Wei, Qiwu Shi, Lidan Xiong, Guang Xin, Tao Yi, Yunqing Xiao, and Wanxia Huang

Subjects
Medicine, Science
Abstract

Abstract The experiment of inertial confinement fusion by the “ShengGuang (SG)-III” prototype laser facility is a transient and extreme reaction process within several nanoseconds, which could form a very complicated and intense electromagnetic field around the target chamber of the facility and may lead to harmful effect on people around. In particular, the biological effects arising from such specific environment field could hardly be ignored and have never been investigated yet, and thus, we reported on the investigation of the biological effects of radiation on HaCat cells and PC12 cells to preliminarily assess the biological safety of the target range of the "SG-III" prototype laser facility. The viability revealed that the damage of cells was dose-dependent. Then we compared the transcriptomes of exposed and unexposed PC12 cells by RNA-Seq analysis based on Illumina Novaseq 6000 platform and found that most significantly differentially expressed genes with corresponding Gene Ontology terms and pathways were strongly involved in proliferation, transformation, necrosis, inflammation response, apoptosis and DNA damage. Furthermore, we find increase in the levels of several proteins responsible for cell-cycle regulation and tumor suppression, suggesting that pathways or mechanisms regarding DNA damage repair was are quickly activated. It was found that "SG-III" prototype radiation could induce DNA damage and promote apoptotic necrosis.

Published
2021
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12. VO2-metallic hybrid metasurfaces for agile terahertz wave modulation by phase transition

Author

Hongfu Zhu, Jiang Li, Lianghui Du, Lijun Shan, Peng Li, Xueguang Lu, Tangdong Feng, Sujit Das, Wanxia Huang, Qiwu Shi, and Liguo Zhu

Subjects
Biotechnology, TP248.13-248.65, Physics, QC1-999
Abstract

The combination of VO2 and metasurfaces has opened an attractive route to dynamically control terahertz (THz) waves based on the giant conductivity change. However, the high-precision control of microfabrication and single performance of conductivity change limit the multifunctional application of VO2-based metasurfaces. Here, we proposed a VO2-metallic hybrid metasurface by in situ depositing high-quality VO2 thin films onto a metasurface composed of asymmetric Fano resonance units. It exhibits agile frequency and amplitude modulation for THz transmission across tuning the dielectric constant and conductivity of VO2. The metallic metasurface is designed as a matrix to achieve high transmission at 0.61 and 0.78 THz due to the split-ring resonance. During the thermally triggered phase transition of VO2, we found that the resonance frequency and amplitude can be tuned dominantly by the change of dielectric constant and conductivity, respectively. In particular, the increased dielectric constant enables red shift of the frequency by around 0.48 THz and the conductivity increases lead to a giant THz amplitude modulation of 88%. These results provide a route for developing VO2-based THz smart devices combined with functional metasurfaces and hold great promise for applications in THz sensor and modulation.

Published
2022
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13. Photothermal conversion of Ti2O3 film for tuning terahertz waves

Author

Yu Cai, Hongfu Zhu, Qiwu Shi, Ye Cheng, Lei Chang, and Wanxia Huang

Subjects
Radiation physics, Radiation sources, Nanotechnology, Science
Abstract

Summary: Dynamic tuning of terahertz (THz) wave is vital for the development of next generation THz devices. Utilization of solar energy for tuning THz waves is a promising, eco-friendly, and sustainable way to expand THz application scenarios. Ti2O3 with an ultranarrow bandgap of 0.1eV exhibits intriguing thermal-induced metal-insulator transition (MIT), and possesses excellent photothermal conversion efficiency. Herein, Ti2O3 film was fabricated by a two-step magnetron sputtering method, and exhibited an excellent photothermal conversion efficiency of 90.45% and demonstrated temperature-dependent THz transmission characteristics with a wideband at 0.1–1 THz. We supposed to combine photothermal conversion characteristics with temperature-dependent THz transmission properties of Ti2O3 film, which could introduce solar light as the energy source for tuning THz waves. Our work will provide new sight for investigating MIT characteristics of Ti2O3 at THz regime and exhibit huge potential in the application of tuning terahertz waves in outdoor scenarios in the future.

Published
2022
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14. On-chip monolithic wide-angle field-of-view metalens based on quadratic phase profile

Author

Cong Chen, Panpan Chen, Jianxin Xi, Wanxia Huang, Kuanguo Li, Li Liang, Fenghua Shi, and Jianping Shi

Subjects
Physics, QC1-999
Abstract

With the rapid development of integrated optics, bulky and curved traditional lenses cannot meet the requirements of on-chip optical systems. Alternatively, the metalenses based on the artificial subwavelength structure possess ultra-thin and lightweight characteristics, providing a potential candidate for on-chip optical systems. Nonetheless, most metalenses have a limited field-of-view (FOV) due to the prevalence of severe off-axis aberrations. In this work, we propose and design an on-chip metalens with wide FOV based on the quadratic phase. The metalens modulates the phase of the incident light with different lengths of gold nano-bands placed on the silicon-on-insulator substrate; thus, the quadratic distribution of the phase of the output light can be achieved by shifting the lengths of gold nano-bands and the output light is focused. The metalens can be focused on a large angle (∼120°, ranging from −60° to +60°). Furthermore, the metallic strips in the metalens are very thin with a thickness of 50 nm, which can be easily integrated into a chip. The monolithic metalens of broad FOV and ultrathin thickness will have great potential for applications in areas of sensing, imaging, and on-chip information processing.

Published
2020
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15. Two-Channel VO2 Memory Meta-Device for Terahertz Waves

Author

Xueguang Lu, Bowen Dong, Hongfu Zhu, Qiwu Shi, Lu Tang, Yidan Su, Cheng Zhang, Wanxia Huang, and Qiang Cheng

Subjects
meta-memory, terahertz, vanadium dioxide, reconfigurable metasurface, Chemistry, QD1-999
Abstract

Vanadium oxide (VO2), as one of the classical strongly correlated oxides with a reversible and sharp insulator-metal transition (IMT), enables many applications in dynamic terahertz (THz) wave control. Recently, due to the inherent phase transition hysteresis feature, VO2 has shown favorable application prospects in memory-related devices once combined with metamaterials or metasurfaces. However, to date, VO2-based memory meta-devices are usually in a single-channel read/write mode, which limits their storage capacity and speed. In this paper, we propose a reconfigurable meta-memory based on VO2, which favors a two-channel read/write mode. Our design consists of a pair of large and small split-ring resonators, and the corresponding VO2 patterns are embedded in the gap locations. By controlling the external power supply, the two operation bands can be controlled independently to achieve at least four amplitude states, including “00”, “01”, “10”, and “11”, which results in a two-channel storage function. In addition, our research may provide prospective applications in fields such as THz switching, photon storage, and THz communication systems in the future.

Published
2021
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17. Broadband terahertz metamaterial absorber based on simple multi-ring structures

Author

Guoqing Shen, Ming Zhang, Yanping Ji, Wanxia Huang, Honglin Yu, and Jianping Shi

Subjects
Physics, QC1-999
Abstract

Single-layer metallic rings are the effective structure cell which are widely used to design single-band and multiband perfect metamaterial absorbers owning to their electromagnetic resonance. However, the absorbers based on the single-layer metallic rings have a common shortcoming, that is the narrow absorption bandwidth. To overcome the limitations, here we proposed a single-layer, flexible and broadband terahertz metamaterial absorber, which consists of four sub-cells with multiple metal rings and a metal ground plane separated by a dielectric layer. By enhancing the coupling response between adjacent metallic rings and merging the adjacent resonant peaks of multi-resonators, we experimentally observed broadband characteristics at the terahertz band. The average absorption of 88% from 0.63 to 1.34 THz and the relative absorption bandwidth of 95% at the incident angle of 15o for TE polarization. Correspondingly, for TM polarization the absorption of more than 80% from 0.61 to 1.1 THz with the relative absorption bandwidth of 80% were also observed. The results went far beyond the previous single-layer absorbers based on metal rings and were much better than the fractal-cross structure reported recently [Kenney et al., ACS Photonics 4, 2604 (2017)]. We had reason to believe that the presented terahertz metamaterial absorber with broad absorption bandwidth and simple structure can find important applications in communication, stealth, energy harvesting systems and so on.

Published
2018
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18. Tuning the Doping Ratio and Phase Transition Temperature of VO2 Thin Film by Dual-Target Co-Sputtering

Author

Xu Chen, Mingfei Wu, Xingxing Liu, Ding Wang, Feng Liu, Yuwei Chen, Fei Yi, Wanxia Huang, and Shaowei Wang

Subjects
VO2, thin films, doping, co-sputtering, phase transition, Chemistry, QD1-999
Abstract

A new simple way for tuning the phase transition temperature (PTT) of VO2 thin films has been proposed to solve the problem of changing the doping ratio by using the dual-target co-sputtering method. A series of samples with W doping ratios of 0%, 0.5%, 1%, 1.5% and 2% have been fabricated by sputtering V films with the power of pure and 2% W-doped V targets from 500 W: 0 W, 500 W: 250 W, 500 W: 500 W, 250 W: 500 W to 0 W: 500 W respectively and then annealed in an oxygen atmosphere to form VO2. The XRD results of both pure and W-doped VO2 samples reveal that VO2 forms and is the main component after annealing. The PTT can be tuned by controlling the sputtering power ratio of the pure and doped targets. It can be tuned easily from 64.3 °C to 36.5 °C by using the pure and 2% W-doped targets for demonstration, with W doping ratios from 0% to 2%. It is also valid for other doping elements and is a promising approach for the large-scale production of sputtering.

Published
2019
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19. A Preliminary Study on Sinus Fungus Ball with MicroCT and X-Ray Fluorescence Technique.

Author

Zidong Jiang, Kai Zhang, Wanxia Huang, and Qingxi Yuan

Subjects
Medicine, Science
Abstract

BACKGROUND:Sinus fungus ball, an accumulation of fungal dense concretions, is a common disease in practice, and might cause fatal complications or lead to death once converted into invasive type. Early preoperative diagnosis of this disease can lead to appropriate treatment for patients and prevent multiple surgical procedures. Up to now, the diagnostic criteria of sinus fungus ball have been defined and computed tomography (CT) scan was considered as a valuable preoperative diagnostic tool. However, the sensitivity of clinical CT is only about 62%. Thus, investigating the factors which influence sensitivity is necessary for clinical CT to be a more valuable preoperative diagnosis tool. Furthermore, CT scan usually presents micro-calcifications or spots with metallic density in sinus fungus ball. Previous literatures show that there are some metallic elements such as calcium and zinc in fungus ball, and they concluded that endodontic treatment has a strong correlation with the development of maxillary sinus fungus ball and zinc ion was an exogenous risk factor. But the pathogenesis of sinus fungus ball still remains unclear because fungus ball can also develop in other non-maxillary sinuses or the maxillary sinus without root canal treatment. Is zinc ion the endogenous factor? Study on this point might be also helpful for investigating the pathogenesis of sinus fungus ball. In this paper, we tried to investigate the factors which influence the sensitivity of clinical CT by imaging sinus fungus ball with microCT. The origin of zinc ion was also studied through elements test for different fungal ball samples using x-ray fluorescence technique. METHODS:Specimens including fungal ball material and sinus mucosa from patients confirmed by pathological findings were extracted after surgery. All fungal ball specimens came from sphenoid sinus, ethmoidal sinus and maxillary sinus with or without previous endodontic treatment respectively. All of them were imaged by microCT with spatial resolution up to 5μm to acquire three-dimensional structure, and then the heavy metal elements were detected with x-ray fluorescence spectrometer analysis. RESULT:High concentration of zinc and calcium were detected in all fungal ball specimens compared to sinus mucosa membrane. Particles with different size varied from disperse to density, which have similar shape to the result of clinical CT but with different size, were found in three-dimensional reconstruction results of microCT. CONCLUSIONS:Spatial resolution is an influent factor of clinical CT sensitivity for sinus fungus ball. Improving the resolution of clinical CT will help to improve its sensitivity. Besides iatrogenic endodontic materials, endogenous metal elements of zinc and calcium might associate with the growth of fungal ball and the micro-calcifications or spots with metallic density of CT imaging.

Published
2016
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20. Influence of Fe-rich phases and precipitates on the mechanical behaviour of Al-Cu-Mn-Fe-Sc-Zr alloys studied by synchrotron X-ray and neutron

Author

Yuliang Zhao, Dongfu Song, Shengchuan Wu, Shunfu Xie, Haoliang Wang, Mengmeng Wang, Weiwen Zhang, Zhenzhong Sun, Yubin Ke, Shanfeng Wang, Wanxia Huang, and Ricardo Fernández

Subjects
Polymers and Plastics, Mechanics of Materials, Mechanical Engineering, Materials Chemistry, Metals and Alloys, Ceramics and Composites
Published
2023
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21. Bulk Microstructure of Modern Composites Studied Jointly by Impulse Acoustic Microscopy and X-ray Microtomography Techniques

Author

Levin, Vadim, Petronyuk, Yulia, Morokov, Egor, Ryzhova, Tatiana, Shanygin, Alexander, Yuan, Qingxi, Wanxia, Huang, Artyukov, Igor, and Bellucci, Stefano

Subjects
Microscopy, Polymers, CAT scans, Polymer industry, Polymer composites, Composite materials, Plastic products, Three-dimensional imaging, Plastics industry, Engineering and manufacturing industries, Science and technology
Abstract

Two key techniques--impulse acoustic microscopy and X-ray microtomography--have been applied in combination for studying bulk microstructure in polymer composites whose properties critically depend on their spatial organization; nanocomposites and fiber reinforced plastics. It has been shown that the both techniques are able to represent three-dimensional (3D) internal structure with micron resolution. The technique is based on different principles of 3D imaging and employs distinct mechanisms of contrast for microstructure displaying. In many cases, they are complementary in 3D microstructure recovering., INTRODUCTION The paper concerns application of two experimental techniques of high-resolution bulk visualization--impulse acoustic microscopy and X-ray microtomography (X-ray [mu]-CT)--for studying internal microstructure in carbon-based composite materials. Interest to composite [...]

Published
2019
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23. Quantitative Insights into a Plasmonic Ruler Equation from the Perspective of Enhanced Near Field

Author

Yong Zhou, Jiahui Zhu, Jin Xi, Kuanguo Li, and Wanxia Huang

Subjects
Physical and Theoretical Chemistry
Abstract

The plasmonic shift of resonance wavelength induced by near-field coupling enables one to measure nanoscale distances optically. Empirically, the well-known ruler equation correlating plasmon shift with interparticle spacing was proposed. Though it has been widely used in analyzing simulation and experimental outcomes, little is known about the underlying physical mechanism of the characteristic exponential form of the plasmon ruler equation and the universal decay constant therein. In this work, we attempt to decrypt these from the perspective of plasmon near-field enhancement. Based on an analytical quasi-normal mode formula for plasmon shifts, we proved that the exponential decaying electric field is the critical reason that results in the exponential form of the plasmon ruler equation and quantitatively, we found that the universal decay constant in the plasmon ruler equation actually reflects the range of the enhanced near field. This work hopefully helps to deepen the understanding of the mechanism of light-matter interaction in corresponding plasmonic processes.

Published
2022
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27. THz medical imaging: from in vitro to in vivo

Author

Zhiyao Yan, Li-Guo Zhu, Kun Meng, Wanxia Huang, and Qiwu Shi

Subjects
Terahertz Imaging, Water, Bioengineering, Biotechnology
Abstract

Terahertz (THz) radiation has attracted considerable attention in medical imaging owing to its nonionizing and spectral fingerprinting characteristics. To date, most studies have focused on in vitro and ex vivo objects with water-removing pretreatment because the water in vivo excessively absorbs the THz waves, which causes deterioration of the image quality. In this review, we discuss how THz medical imaging can be used for a living body. The development of imaging contrast agents has been particularly useful to this end. In addition, we also introduce progress in novel THz imaging methods that could be more suitable for in vivo applications. Based on our discussions, we chart a developmental roadmap to take THz medical imaging from in vitro to in vivo.

Published
2022
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33. Stereoselective coronas regulate the fate of chiral gold nanoparticles in vivo

Author

Didar Baimanov, Liming Wang, Ke Liu, Mengmeng Pan, Rui Cai, Hao Yuan, Wanxia Huang, Qingxi Yuan, Yunlong Zhou, Chunying Chen, and Yuliang Zhao

Subjects
General Materials Science
Abstract

Formation of chirality-specific protein corona on gold nanoparticles promotes recognition by lipoproteins, complements, and acute phase proteins that mediates LDL receptor-involved cell uptake and tissue accumulation in vivo.

Published
2023
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34. Feature detection network-based correction method for accurate nano-tomography reconstruction

Author

Tianyu Fu, Kai Zhang, Yan Wang, Shanfeng Wang, Jin Zhang, Chunxia Yao, Chenpeng Zhou, Wanxia Huang, and Qingxi Yuan

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

Driven by the development of advanced x-ray optics such as Fresnel zone plates, nano-resolution full-field transmission x-ray microscopy (Nano-CT) has become a powerful technique for the non-destructive volumetric inspection of objects and has long been developed at different synchrotron radiation facilities. However, Nano-CT data are often associated with random sample jitter because of the drift or radial/axial error motion of the rotation stage during measurement. Without a proper sample jitter correction process prior to reconstruction, the use of Nano-CT in providing accurate 3D structure information for samples is almost impossible. In this paper, to realize accurate 3D reconstruction for Nano-CT, a correction method based on a feature detection neural network, which can automatically extract target features from a projective image and precisely correct sample jitter errors, is proposed, thereby resulting in high-quality nanoscale 3D reconstruction. Compared with other feature detection methods, even if the target feature is overlapped by other high-density materials or impurities, the proposed Nano-CT correction method still acquires sub-pixel accuracy in geometrical correction and is more suitable for Nano-CT reconstruction because of its universal and faster correction speed. The simulated and experimental datasets demonstrated the reliability and validity of the proposed Nano-CT correction method.

Published
2022

35. Terahertz switchable VO

Author

Bowen, Dong, Ruizhe, Zhao, Qunshuo, Wei, Xueguang, Lu, Wanxia, Huang, Jiafu, Wang, Hua, Ma, and Lingling, Huang

Abstract

The combination of metasurface and holographic technology is the most cutting-edge development, but most of the proposed designs are static and do not allow active changes through external stimulation after fabrication, which takes only a limited part of the advantage provided by metasurface. Here, we propose and demonstrate a switchable hybrid active metasurface hologram in the terahertz (THz) regime composed of dynamic pixels (VO

Published
2022

36. Deep-learning-based image registration for nano-resolution tomographic reconstruction

Author

Wanxia Huang, Kai Zhang, Jizhou Li, Yan Wang, Qingxi Yuan, Chunxia Yao, Tianyu Fu, Jin Zhang, Qili He, Yijin Liu, Shanfeng Wang, and Piero Pianetta

Subjects
Nuclear and High Energy Physics, Radiation, Source code, Tomographic reconstruction, business.industry, Computer science, media_common.quotation_subject, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Process (computing), Image registration, Field (computer science), Range (mathematics), Transmission (telecommunications), Computer vision, Artificial intelligence, business, Instrumentation, media_common, Jitter
Abstract

Nano-resolution full-field transmission X-ray microscopy has been successfully applied to a wide range of research fields thanks to its capability of non-destructively reconstructing the 3D structure with high resolution. Due to constraints in the practical implementations, the nano-tomography data is often associated with a random image jitter, resulting from imperfections in the hardware setup. Without a proper image registration process prior to the reconstruction, the quality of the result will be compromised. Here a deep-learning-based image jitter correction method is presented, which registers the projective images with high efficiency and accuracy, facilitating a high-quality tomographic reconstruction. This development is demonstrated and validated using synthetic and experimental datasets. The method is effective and readily applicable to a broad range of applications. Together with this paper, the source code is published and adoptions and improvements from our colleagues in this field are welcomed.

Published
2021
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37. Accurate reconstruction algorithm for bilateral differential phase signals

Author

Chunxia Yao, Peiping Zhu, Shanfeng Wang, Jin Zhang, Tianyu Fu, Wanxia Huang, Kai Zhang, Peng Liu, Qili He, Yan Wang, Panyun Li, and Qingxi Yuan

Subjects
Nuclear and High Energy Physics, Computer science, business.industry, Reconstruction algorithm, Signal, Sample (graphics), Refraction, Streaking, Differential phase, Data acquisition, Nuclear Energy and Engineering, Perpendicular, Computer vision, Artificial intelligence, business
Abstract

The differential phase computed tomography (DP-CT) imaging is a kind of X-ray-phase-based CT methods, which is widely used in various X-ray imaging laboratories. At present, a collection of projections with the horizontal direction (perpendicular to the sample rotation axis) DP information is often acquired in DP-CT. In an ideal experiment, if the background is zero, then we can accurately reconstruct the information of each direction of the sample with horizontal data only. Actually, background information will produce streaking artifacts to affect the resolution in directions other than the horizontal direction. To mitigate the streaking artifacts in the conventionally reconstructed DP-CT images. This study develops a novel analytical DP-CT reconstruction framework by jointly using the bilateral DP information obtained along two perpendicular directions. In addition, a new data acquisition scheme is also proposed to quickly acquire the bilateral DP signal without the need of changing the direction of refraction signal acquisition. Experimental results demonstrate that this new algorithm is able to greatly reduce the streaking artifacts on DP-CT images.

Published
2021
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39. Cu/Al

Author

Xinyu, Zhou, Pin, Mao, Huiran, Jin, Wanxia, Huang, Aotian, Gu, Kaiwei, Chen, Shan, Yun, Jing, Chen, and Yi, Yang

Abstract

Cu-based functional materials are excellent candidates for the elimination of iodine anions. However, the low utilization rate of Cu and its unsatisfactory adsorption performance limit its large-scale practical applications. This paper proposes a co-gelation method to obtain Cu/Al

Published
2022

43. Impact of the uniaxial strain on terahertz modulation characteristics in flexible epitaxial VO2 film across the phase transition

Author

Xue Chang, Jiang Li, Jian Mu, Chun-Hao Ma, Wanxia Huang, Hong-Fu Zhu, Qiao Liu, Liang-Hui Du, Sen-Cheng Zhong, Zhao-Hui Zhai, Sujit Das, Yen-Lin Huang, Gang-Bei Zhu, Li-Guo Zhu, and Qiwu Shi

Subjects
Atomic and Molecular Physics, and Optics
Abstract

Exploring flexible electronics is on the verge of innovative breakthroughs in terahertz (THz) communication technology. Vanadium dioxide (VO2) with insulator-metal transition (IMT) has excellent application potential in various THz smart devices, but the associated THz modulation properties in the flexible state have rarely been reported. Herein, we deposited an epitaxial VO2 film on a flexible mica substrate via pulsed-laser deposition and investigated its THz modulation properties under different uniaxial strains across the phase transition. It was observed that the THz modulation depth increases under compressive strain and decreases under tensile strain. Moreover, the phase-transition threshold depends on the uniaxial strain. Particularly, the rate of the phase transition temperature depends on the uniaxial strain and reaches approximately 6 °C/% in the temperature-induced phase transition. The optical trigger threshold in laser-induced phase transition decreased by 38.9% under compressive strain but increased by 36.7% under tensile strain, compared to the initial state without uniaxial strain. These findings demonstrate the uniaxial strain-induced low-power triggered THz modulation and provide new insights for applying phase transition oxide films in THz flexible electronics.

Published
2023
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44. Optical-Transparent Self-Assembled MXene Film with High-Efficiency Terahertz Reflection Modulation

Author

Hongfu Zhu, Sujit Das, Wanxia Huang, Xueguang Lu, Qiwu Shi, and Tangdong Feng

Subjects
Materials science, Terahertz radiation, business.industry, Impedance matching, 02 engineering and technology, Conductivity, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Reflection (mathematics), Modulation, Optoelectronics, General Materials Science, Self-assembly, 0210 nano-technology, Biological imaging, business, Electrical impedance
Abstract

The modulation of the terahertz (THz) wave is fundamental for its applications in next-generation communications, biological imaging, sensing, and so forth. Searching for higher efficient modulation is still in progress, although plenty of materials have been explored for tuning THz wave. In this work, optical-transparent self-assembled MXene films are used to modulate the THz reflection at the SiO2/MXene/air interface based on the impedance matching mechanism. By adjusting the number of stacked MXene layers/concentrations of MXene dispersions, the sheet conductivity of the MXene films will be changed so that the impedance at the SiO2/MXene/air interface can be tuned and lead to a giant modulation of THz reflection. Particularly, we demonstrate that the MXene films have highly efficient THz modulation from antireflection to reflection-enhancing with a relative reflection of 27% and 406%, respectively. This work provides a new pathway for developing the MXene films with the combination of optical-transparency and high smart THz reflection characteristics, and the films can be applied for THz antireflection or reflection-enhancing.

Published
2021
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45. Transcriptome profiling of cells exposed to particular and intense electromagnetic radiation emitted by the 'SG-III' prototype laser facility

Author

Lidan Xiong, Guang Xin, Yunqing Xiao, Tao Yi, Qiwu Shi, Wanxia Huang, and Jiangbin Wei

Subjects
Cell biology, DNA Repair, Molecular biology, DNA damage, Science, Biophysics, Apoptosis, Inflammation, PC12 Cells, Electromagnetic radiation, Article, law.invention, Transcriptome, law, Genetics, medicine, Animals, Humans, Transcriptome profiling, Multidisciplinary, Chemistry, Electromagnetic Radiation, Gene Expression Profiling, Lasers, High-Throughput Nucleotide Sequencing, Cell Cycle Checkpoints, Laser, Rats, HaCaT, Medicine, medicine.symptom, Neuroscience, DNA Damage
Abstract

The experiment of inertial confinement fusion by the “ShengGuang (SG)-III” prototype laser facility is a transient and extreme reaction process within several nanoseconds, which could form a very complicated and intense electromagnetic field around the target chamber of the facility and may lead to harmful effect on people around. In particular, the biological effects arising from such specific environment field could hardly be ignored and have never been investigated yet, and thus, we reported on the investigation of the biological effects of radiation on HaCat cells and PC12 cells to preliminarily assess the biological safety of the target range of the "SG-III" prototype laser facility. The viability revealed that the damage of cells was dose-dependent. Then we compared the transcriptomes of exposed and unexposed PC12 cells by RNA-Seq analysis based on Illumina Novaseq 6000 platform and found that most significantly differentially expressed genes with corresponding Gene Ontology terms and pathways were strongly involved in proliferation, transformation, necrosis, inflammation response, apoptosis and DNA damage. Furthermore, we find increase in the levels of several proteins responsible for cell-cycle regulation and tumor suppression, suggesting that pathways or mechanisms regarding DNA damage repair was are quickly activated. It was found that "SG-III" prototype radiation could induce DNA damage and promote apoptotic necrosis.

Published
2021

47. In-situ studies and simulation of equiaxed solidification in Al–20Cu alloy

Author

Lei Xiao, Guangyu Yang, Shifeng Luo, Qingxi Yuan, Wanqi Jie, Wanxia Huang, and Jieming Chen

Subjects
010302 applied physics, Equiaxed crystals, In situ, Materials science, Mechanical Engineering, Metallurgy, Alloy, 02 engineering and technology, Cooling rates, engineering.material, equipment and supplies, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Synchrotron, Grain size, law.invention, Cooling rate, Mechanics of Materials, law, 0103 physical sciences, engineering, General Materials Science, 0210 nano-technology
Abstract

The equiaxed solidification of Al–20Cu alloy under different cooling rates was investigated using in-situ synchrotron X-ray radiography. The results showed that mean grain size increases rapidly at...

Published
2020
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48. A New Diarylbenzophenone from Selaginella tamariscina

Author

Hui Zou, Xi-Feng Sheng, Xinyu Quan, Dan Zhang, Yujie Peng, Qiong Zhao, Yixiao Luo, Wanxia Huang, Wanling Chen, and Lu Zhou

Subjects
Pharmacology, Traditional medicine, Organic Chemistry, Drug Discovery, Selaginella tamariscina, Plant Science, Biology
Published
2020
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49. A complete phase diagram for dark-bright coupled plasmonic systems: applicability of Fano’s formula

Author

Tong Liu, Qiong He, Jing Lin, Lei Zhou, Meng Qiu, Wanxia Huang, and Shiyi Xiao

Subjects
coupled plasmonic systems, 73.20.mf, QC1-999, 42.25.hz, 02 engineering and technology, Fano plane, Coupled mode theory, 01 natural sciences, Nanomaterials, fano resonance, 0103 physical sciences, Electrical and Electronic Engineering, 010306 general physics, Plasmon, Phase diagram, Physics, fano’s formula, Condensed matter physics, Fano resonance, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, coupled-mode theory, Electronic, Optical and Magnetic Materials, 07.07.df, 0210 nano-technology, Biotechnology
Abstract

Although coupled plasmonic systems have been extensively studied in the past decades, their theoretical understanding is still far from satisfactory. Here, based on experimental and numerical studies on a series of symmetry-broken nano-patch plasmonic resonators, we found that Fano’s formula, widely used in modeling such systems previously, works well for one polarization but completely fails for another polarization. In contrast, a two-mode coupled-mode theory (CMT) can interpret all experimental results well. This motivated us to employ the CMT to establish a complete phase diagram for such coupled plasmonic systems, which not only revealed the diversified effects and their governing physics in different phase regions, but more importantly, also justifies the applicabilities of two simplified models (including Fano’s formula) derived previously. Our results present a unified picture for the distinct effects discovered in such systems, which can facilitate people’s understanding of the governing physics and can design functional devices facing requests for diversified applications.

Published
2020
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50. Synthesis of CoV2O6/CNTs composites via ultrasound as electrode materials for supercapacitors

Author

Lu Tang, Xiang Lv, Jibin Tang, Wanxia Huang, and Qiwu Shi

Subjects
010302 applied physics, Supercapacitor, Materials science, Chemical substance, Annealing (metallurgy), Condensed Matter Physics, 01 natural sciences, Capacitance, Atomic and Molecular Physics, and Optics, Energy storage, Electronic, Optical and Magnetic Materials, law.invention, Magazine, law, 0103 physical sciences, Electrical and Electronic Engineering, Composite material, Science, technology and society, Power density
Abstract

A rod-like CoV2O6 material was synthesized via ultrasound and subsequent annealing treatment. The as-prepared CoV2O6/CNTs composites exhibited higher capacitance performance than that of pristine CoV2O6. The obtained CoV2O6/CNTs composites exhibited a large specific capacitance of 226.3 F/g at 1 A/g, good rate capability and excellent cyclic stability with 88% retention of its initial value after 9000 cycles. Also, the assembled devices delivered an energy density of 13.8 Wh/kg at a power density of 800 W/kg and a high power density of 8000 W/kg at an energy density of 11.6 Wh/kg. This work may provide a novel strategy to design and fabricate other energy storage materials for high-performance supercapacitors.

Published
2020
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