Your search keyword '"Kang, Lei"' showing total 16 results

1. Flexible terahertz spoof plasmonics based on graphene-assembled films.

Author

Zhang, Bohan, He, Dapeng, Zhang, Qian, Fang, Jiaxing, Lu, Xueguang, Huang, Wanxia, Chen, Zibo, He, Daping, Kang, Lei, Werner, Douglas H., and Wang, Shengxiang

Subjects

TERAHERTZ technology, PLASMONICS, ELECTRIC conductivity, THERMAL stability

Abstract

Spoof plasmonics, which can enable strong terahertz (THz) radiation–matter interactions, hold great promise for the advancement of THz science and technology. However, THz spoof plasmonic devices based on micro-structured metals are in general limited by lithography-based fabrication processes as well as metals' mechanical, chemical, and thermal stability, which hinders their applications in, for instance, flexible and wearable THz imaging and communications, molecular sensing, etc. Possessing high electrical conductivity and outstanding mechanical robustness, graphene-assembled films (GAFs) promise many benefits for electronics as an alternative to metals. Here, by studying the resonance-enhanced transmission properties of subwavelength GAF hole arrays, we demonstrate a GAF metasurface as a transformative platform for flexible THz spoof plasmonics. Based on a laser direct writing (LDW) patterning technique, the proposed micro-engineered GAF is expected to pave the way toward large-area, durable, and inexpensive THz metadevices with superior flexibility. [ABSTRACT FROM AUTHOR]

Published

2024

2. Microstructure and mechanical properties of Cr films with different orientations before and after plasma nitriding.

Author

Zhang, Jianting, Li, Dejun, Guo, Yuanyuan, Shang, Deli, Liu, Shuqi, Kang, Lei, Zhang, Lin, Yang, Yongjie, Wang, Xinggang, and Xin, Ning

Subjects

NITRIDING, AUSTENITIC stainless steel, BODY centered cubic structure, MAGNETRON sputtering, WEAR resistance, MICROSTRUCTURE

Abstract

In this paper, the Cr films with preferred orientation evolution from (110) to (200) were deposited on the surface of austenitic stainless steel. These films were driven by a pulsed bias with different duty cycles from 20% to 80%, followed by a postnitriding process for 1 h using a hot wire plasma-enhanced magnetron sputtering system. XRD result showed Cr film had a body-centered cubic lattice structure, and the orientation transformed from (110) to (200) with the increase in the duty cycle. SEM and EDS measurements revealed that Cr film structured with columnar crystals could contribute to the continuous diffusion of nitrogen into austenite lattice. N atoms tended to diffuse along the (200) orientation of Cr films than the close-packed (110) orientation. As a result, the best wear resistance and adhesion strength were obtained when Cr film deposited at 80% duty cycle was nitrided, and the wear volume decreased by 95.7% compared with that before nitriding. [ABSTRACT FROM AUTHOR]

Published

2024

3. Exploiting plasmons in 2D metals for refractive index sensing: Simulation study.

Author

Kang, Lei, Robinson, Joshua A., and Werner, Douglas H.

Subjects

*REFRACTIVE index, *THIN films, *PLASMONICS, *METALS, *NANORIBBONS, *METALLIC films, *SENSES

Abstract

Ultrathin and two-dimensional (2D) metals can support strong plasmons, with concomitant tight field confinement and large field enhancement. Accordingly, 2D-metal nanostructures exhibiting plasmonic resonances are highly sensitive to the environment and intrinsically suitable for optical sensing. Here, based on a proof-of-concept numerical study, nano-engineered ultrathin 2D-metal films that support infrared plasmons are demonstrated to enable highly responsive refractive index (RI) sensing. For 3 nm-Au nanoribbons exhibiting plasmonic resonances at wavelengths around 1600 nm, a RI sensitivity of SRI > 650 nm per refractive index unit (RIU) is observed for a 100 nm-thick analyte layer. A parametric study of the 2D-Au system indicates the strong dependence of the RI sensitivity on the 2D-metal thickness. Furthermore, for an analyte layer as thin as 1 nm, a RI sensitivity up to 110 (90 nm/RIU) is observed in atomically thin 2D-In (2D-Ga) nanoribbons exhibiting highly localized plasmonic resonances at mid-infrared wavelengths. Our results not only reveal the extraordinary sensing characteristics of 2D-metal systems but also provide insight into the development of 2D-metal-based plasmonic devices for enhanced IR detection. [ABSTRACT FROM AUTHOR]

Published

2022

4. Label-free and non-destructive histology of unprocessed biological tissues with ultraviolet single-plane illumination microscopy.

Author

Zhang, Yan, Huang, Bingxin, Dai, Weixing, Kang, Lei, Tsang, Victor T. C., Wu, Jiajie, Lo, Claudia T. K., and Wong, Terence T. W.

Subjects

TISSUES, HISTOLOGY, MICROSCOPY, LUNGS, SURGICAL margin, SURGICAL pathology

Abstract

Histopathology has remained the gold standard for surgical margin assessment for decades. However, routine pathological examination based on formalin-fixed and paraffin-embedded (FFPE) tissues is laborious and time-consuming, failing to guide surgeons intraoperatively. Here, we propose a rapid, label-free, and non-destructive histological imaging method, termed microscopy with ultraviolet single-plane illumination (MUSI). With intrinsic fluorescence from deep ultraviolet excitation, MUSI enables both ex vivo and in vivo imaging of fresh and unprocessed tissues at the subcellular level with an imaging speed of 0.5 mm2/s, generating high-quality optically sectioned surface images from irregular surgical tissues with a long depth-of-field. We demonstrate that MUSI could differentiate between different subtypes of human lung adenocarcinomas (e.g., lepidic, acinar, papillary, and micropapillary), revealing diagnostically important features that are comparable to the gold standard FFPE histology. As an assistive imaging platform, MUSI can provide immediate feedback to surgeons and pathologists for intraoperative decision-making, holding great promise to revolutionize the current clinical practice in surgical pathology. [ABSTRACT FROM AUTHOR]

Published

2024

5. Linear and nonlinear chiroptical response from individual 3D printed plasmonic and dielectric micro-helices.

Author

Famularo, Nicole R., Kang, Lei, Li, Zehua, Zhao, Tian, Knappenberger, Kenneth L., Keating, Christine D., and Werner, Douglas H.

Subjects

*SECOND harmonic generation, *CIRCULAR dichroism, *MICROSCOPY, *NONLINEAR optical spectroscopy, *OPTICAL spectroscopy, *DIELECTRICS, *NEAR-field microscopy

Abstract

Sub-wavelength chiral resonators formed from artificial structures exhibit exceedingly large chiroptical responses compared to those observed in natural media. Owing to resonant excitation, chiral near fields can be significantly enhanced for these resonators, holding great promise for developing enantioselective photonic components such as biochemical sensors based on circular dichroism (CD) and spin-dependent nonlinear imaging. In the present work, strong linear and nonlinear chiroptical responses (scattering CD > 0.15 and nonlinear differential CDs > 0.4) at visible and near infrared frequencies are reported for the first time for individual micrometer-scale plasmonic and dielectric helical structures. By leveraging dark-field spectroscopy and nonlinear optical microscopy, the circular-polarization-selective scattering behavior and nonlinear optical responses (e.g., second harmonic generation and two-photon photoluminescence) of 3D printed micro-helices with feature sizes comparable to the wavelength (total length is ∼5λ) are demonstrated. These micro-helices provide potential for readily accessible photonic platforms, facilitating an enantiomeric analysis of chiral materials. One such example is the opportunity to explore ultracompact photonic devices based on single, complex meta-atoms enabled by state-of-the-art 3D fabrication techniques. [ABSTRACT FROM AUTHOR]

Published

2020

6. First-principles study of electronic and diffusion properties of intrinsic defects in 4H-SiC.

Author

Yan, Xiaolan, Li, Pei, Kang, Lei, Wei, Su-Huai, and Huang, Bing

Subjects

WIDE gap semiconductors, POINT defects, DIFFUSION barriers, DIFFUSION, ACTIVATION energy

Abstract

As a wide bandgap semiconductor, SiC holds great importance for high temperature and high power devices. It is known that the intrinsic defects play key roles in determining the overall electronic properties of semiconductors; however, a comprehensive understanding of the intrinsic defect properties in the prototype 4H-SiC is still lacking. In this study, we have systematically investigated the electronic properties and kinetic behaviors of intrinsic point defects and defect complexes in 4H-SiC using advanced hybrid functional calculations. Our results show that all the point defects in 4H-SiC have relatively high formation energies, i.e., low defect concentrations even at high growth temperatures. Interestingly, it is found that the migration barriers are very high for vacancies (>3 eV) but relatively low for interstitial defects (∼1 eV) in SiC. Meanwhile, the diffusion energy barriers of defects strongly depend on their charge states due to the charge-state-dependent local environments. Furthermore, we find that VSi in SiC, a key defect for quantum spin manipulation, is unstable compared to the spin-unpolarized VC–CSi complex in terms of the total energy (under p-type conditions). Fortunately, the transformation barrier from VSi to VC–CSi is as high as 4 eV, which indicates that VSi could be stable at room (or not very high) temperature. [ABSTRACT FROM AUTHOR]

Published

2020

7. 3D printed metamaterial absorbers for mid-infrared surface-enhanced spectroscopy.

Author

Hendrickson-Stives, Albanie K., Kang, Lei, Donahue, Nicole R., Keating, Christine D., and Werner, Douglas H.

Subjects

*METAMATERIALS, *MOLECULAR vibration, *DNA fingerprinting, *SPECTROMETRY, *INFRARED absorption, *DEGREES of freedom, *INFRARED radiation

Abstract

The resonant nature and geometric scalability make metamaterials an ideal platform for an enhanced light–matter interaction over a broad frequency range. The mid-infrared (IR) spectral range is of great importance for vibrational spectroscopy of molecules, while IR metamaterials created from lithography-based planar nanostructures have been used to demonstrate enhanced molecular detection. Compared with visible and near-infrared, the relative long wavelengths of IR light make it possible to achieve three-dimensional (3D) IR metamaterials via the state-of-the-art 3D fabrication techniques. Here, we design and fabricate a 3D printed plasmonic metamaterial absorber (MMA), and by performing Fourier-transform IR spectroscopy, we demonstrate that a series of molecular fingerprint vibrations of glycine can be significantly enhanced by the high absorption mode supported by the 3D meta-atoms of the MMA. The observed enhanced IR detection can also be partially attributed to the improved accessibility offered by the 3D architecture of the MMA. In particular, due to capillary forces during the drying process, the microscale 3D printed features lead to selective analyte deposition in high-field regions, which provides another degree of freedom in the design of the 3D printed structures for surface-enhanced IR detection. Our study shows the flexibility of metastructures based on advanced 3D printing technology in tailoring the interaction between IR light and materials on a subwavelength scale. [ABSTRACT FROM AUTHOR]

Published

2022

8. Modeling of Lorentz forces and radiated wave fields for bulk wave electromagnetic acoustic transducers.

Author

Zhai, Guofu, Wang, Kaican, Wang, Yakun, Su, Riliang, and Kang, Lei

Subjects

FINITE element method, ACOUSTIC transducers, NUMERICAL analysis, TRANSDUCERS, EIGENFUNCTIONS

Abstract

Currently, the finite element method (FEM) and analytical calculation are widely employed for the modeling of electromagnetic acoustic transducers (EMATs). However, it takes long time for finite element calculation. Previous analytical models for bulk wave EMATs are generally considered separately and incompletely, and expressions of radiated wave fields contain infinite integrations and multiple singular points, which result in complex numerical computation. A complete model containing the Lorentz force and radiated wave field calculation for the EMAT with a spiral coil and a NdFeB permanent magnet is established. By introducing a current loop instead of the permanent magnet and adopting the truncated region eigenfunction expansion (TREE) method, the distributions of static and dynamic magnetic fields and their generated Lorentz forces are calculated. A series expansion method is proposed for the computation of radiated wave fields, which replaces the integration by series operation and avoids the solutions of singular points effectively. The Lorentz forces and radiated wave fields of a typical transducer are computed. The validity of the model is verified by FEM and experiments. Their good agreements verify the accuracy and validity of the model. [ABSTRACT FROM AUTHOR]

Published

2013

9. Analysis of wavelength deviation of guided waves with electromagnetic acoustic transducers.

Author

Zhai, Guofu, Jiang, Tao, and Kang, Lei

Subjects

WAVELENGTHS, LENGTH measurement, WAVES (Physics), ELECTROMAGNETISM, ACOUSTIC transducers

Abstract

It is usually considered that the wavelength of guided waves propagating in plates is equal to the double spacing interval of the meander-line coil of electromagnetic acoustic transducers (EMATs). However, the actual value of the wavelength might deviate from the double spacing. This paper takes Shear Horizontal (SH) waves for instance to study the relationship between the wavelength deviation and the parameters of EMATs. It is shown that the wavelength deviation occurs when the operating point of EMATs does not locate on the dispersion curves of a certain SH mode. A wavelength measurement method is proposed to evaluate the deviation by the time-frequency analysis of detected wave signals. Experiments are set up to study the phenomenon of wavelength deviation and verify the validity of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2012

10. Wideband electromagnetic dynamic acoustic transducers (WEMDATs) for air-coupled ultrasonic applications.

Author

Kang, Lei, Feeney, Andrew, and Dixon, Steve

Subjects

*LORENTZ force, *TRANSDUCERS, *PIEZOELECTRIC materials, *DIELECTRIC materials, *ELECTROMAGNETIC fields

Abstract

Achieving sufficient energy transmission over a wide frequency range is a challenge which has restricted the application of many types of air-coupled ultrasonic transducers. Conventional transducer configurations such as the piezoelectric micromachined or flexural ultrasonic transducers can be considered as narrowband. This study reports a type of ultrasonic transducer, the wideband electromagnetic dynamic acoustic transducer (WEMDAT), which operates through a combination of electromagnetic induction and Lorentz force with dynamic behaviour of a micro-scale-thick conductive film. WEMDAT prototypes have been designed, fabricated, and tested, showing their compatibility with both low and high power inputs, operating efficiently as a wideband transmitter from 46.4 kHz to 144.6 kHz with a good directivity. The WEMDAT has also been shown to operate effectively as a wideband ultrasonic receiver through the measurement in a pitch-catch configuration. The WEMDAT prototypes possess an adjustable drive coil lift-off distance from the active membrane, providing flexibility for optimizing the sensitivity of the transducers for different input levels. The performance of the WEMDATs can be optimized, showing significant potential for air-coupled ultrasonic applications. [ABSTRACT FROM AUTHOR]

Published

2019

11. Asymmetric transmission based on magnetic resonance coupling in 3D-printed metamaterials.

Author

Wei, Guochao, Qin, Zhengpeng, Wang, Shengxiang, Wang, Xiaochuan, Lei, Wen, Li, Yuan, Jiang, Zhi Hao, Kang, Lei, and Werner, Douglas H.

Subjects

METAMATERIALS, ELECTROMAGNETIC waves, THREE-dimensional printing, CIRCULAR dichroism, BIREFRINGENCE

Abstract

The resonance based strong light-matter interaction in metamaterials offers unprecedented opportunities to manipulate polarization of electromagnetic waves. In this work, we fabricate a three-dimensional (3D) metamaterial consisting of 90°-twisted split-tube resonators using a 3D printing technique and demonstrate the corresponding asymmetric transmission for linearly polarized electromagnetic waves in the Ku band with near-unity polarization conversion efficiency. Experimental results reveal a 90° polarization rotation and an incident polarization angle dependent asymmetric transmission at a frequency around 15.2 GHz. The experimental results are in good agreement with simulations. Possessing the merits of both flexibility of response tailoring and ease of fabrication, the proposed 3D-printed metamaterials have great potential for compact polarization-control devices exhibiting unidirectional transmission at both microwave and terahertz frequencies. [ABSTRACT FROM AUTHOR]

Published

2018

12. Bandgaps in the deep ultraviolet borate crystals: Prediction and improvement.

Author

He, Ran, Huang, Hongwei, Kang, Lei, Yao, Wenjiao, Jiang, Xingxing, Lin, Zheshuai, Qin, Jingui, and Chen, Chuangtian

Subjects

BAND gaps, BORATE crystals, ELECTRIC insulators & insulation, DENSITY functional theory, NONLINEAR optical materials, SEMICONDUCTORS

Abstract

We identify the microscopic structural origins determining the bandgaps in the deep-ultraviolet borates, and propose an efficient method for the prediction of their bandgaps. This method considers only the chemical bond lengths around oxygen atoms and achieves the very high precision with the relative error <5% typically. Its validity is verified by the first-principles studies, which reveal the strong dependence of bandgaps on the coordination environment around oxygen atoms. Our studies have great implications on the search and design of optoelectronic functional materials with large bandgap. [ABSTRACT FROM AUTHOR]

Published

2013

13. Tunable negative permeability in an isotropic dielectric composite.

Author

Zhao, Qian, Du, Bo, Kang, Lei, Zhao, Hongjie, Xie, Qin, Li, Bo, Zhang, Xing, Zhou, Ji, Li, Longtu, and Meng, Yonggang

Subjects

PERMEABILITY, MAGNETIC resonance, DIELECTRICS, METAMATERIALS, PERMITTIVITY, MATHEMATICAL models, CURIE temperature, ELECTROMAGNETIC fields

Abstract

A tunable isotropic negative effective permeability is experimentally demonstrated in a three-dimensional (3D) dielectric composite consisting of dielectric ceramic cube arrays by temperature changing. It shows that a strong subwavelength magnetic resonance can be excited in dielectric cubes corresponding to the first Mie resonance mode and can be continuously and reversibly adjusted from 13.65 to 19.28 GHz with the temperature changing from -15 to 35 °C. Accordingly, negative permeability can be performed in the frequency range of about 6 GHz by adjusting the temperature. It provides a convenient route to design adaptive metamaterials and 3D invisible cloak. [ABSTRACT FROM AUTHOR]

Published

2008

14. Magnetotunable left-handed material consisting of yttrium iron garnet slab and metallic wires.

Author

Zhao, Hongjie, Zhou, Ji, Zhao, Qian, Li, Bo, Kang, Lei, and Bai, Yang

Subjects

ELECTROMAGNETISM, PERMITTIVITY, MAGNETIC permeability, YTTRIUM iron garnet, FERROMAGNETIC materials

Abstract

A magnetotunable left-handed material (LHM) consisting of yttrium iron garnet (YIG) slab and metallic wires has been demonstrated by experiments and simulations. The left-handed passband through the LHM can be dynamically and continuously tuned in a wide frequency region by an applied magnetic field. The tunability of the passband is attributed to that of the negative permeability induced by ferromagnetic resonance in the YIG slab. The authors proposed a convenient means to design tunable LHM based on the ferromagnetic materials as an alternative to tunable split ring resonators. [ABSTRACT FROM AUTHOR]

Published

2007

15. Experimental verification of a tunable optical negative refraction in nematic liquid crystals.

Author

Kang, Lei, Zhao, Qian, Li, Bo, Zhou, Ji, and Zhu, Hao

Subjects

*LIQUID crystals, *ANISOTROPY, *REFRACTION (Optics), *MAGNETIC fields, *PRISMS

Abstract

The authors experimentally demonstrate a magnetically tunable optical negative refraction (NR) in nematic liquid crystals (NLCs), arising from the variation of optical anisotropy in the NLCs induced by external magnetic field. By measuring the refraction angle of the transmitted beam through the prism-shaped NLC device, the tunable extraordinary refractions for different molecular directions using magnetic field are observed. It shows that NR in NLCs occurs at certain inclination angle and can be tuned by changing the direction of the magnetic field, which is in good agreement with the established theory. [ABSTRACT FROM AUTHOR]

Published

2007

16. Electrically tunable negative permeability metamaterials based on nematic liquid crystals.

Author

Zhao, Qian, Kang, Lei, Du, Bo, Li, Bo, Zhou, Ji, Tang, Hong, Liang, Xiao, and Zhang, Baizhe

Subjects

*METAMATERIALS, *LIQUID crystals, *RESONATORS, *MAGNETIC resonance, *ELECTROMAGNETIC fields, *ELECTRIC fields

Abstract

An electrically tunable negative permeability metamaterial consisting of a periodic array of split ring resonators infiltrated with nematic liquid crystals is demonstrated. It shows that the transmitted resonance dip of the metamaterial can be continuously and reversibly adjusted by an applied electric field, and the maximum shift is about 210 MHz with respect to the resonance frequency around 11.08 GHz. Numerical simulation shows that the permeability is negative near the resonance frequency, and the frequency range with negative permeability can be dynamically adjusted and widened by about 200 MHz by the electric field. It provides a convenient means to design adaptive metamaterials. [ABSTRACT FROM AUTHOR]

Published

2007