Your search keyword '"Xiao-jun Liu"' showing total 19 results

1. One-dimensional PT -symmetric acoustic heterostructure

Author

Hai-Xiao Zhang, Wei Xiong, Ying Cheng, and Xiao-Jun Liu

Subjects

General Physics and Astronomy

Abstract

The explorations of parity–time ( P T )-symmetric acoustics have resided at the frontier in physics, and the pre-existing accessing of exceptional points typically depends on Fabry–Perot resonances of the coupling interlayer sandwiched between balanced gain and loss components. Nevertheless, the concise P T -symmetric acoustic heterostructure, eliminating extra interactions caused by the interlayer, has not been researched in depth. Here we derive the generalized unitary relation for one-dimensional (1D) P T -symmetric heterostructure of arbitrary complexity, and demonstrate four disparate patterns of anisotropic transmission resonances (ATRs) accompanied by corresponding spontaneous phase transitions. As a special case of ATR, the occasional bidirectional transmission resonance reconsolidates the ATR frequencies that split when waves incident from opposite directions, whose spatial profiles distinguish from a unitary structure. The derived theoretical relation can serve as a predominant signature for the presence of P T symmetry and P T -symmetry-breaking transition, which may provide substantial support for the development of prototype devices with asymmetric acoustic responses.

Published

2022

2. Bohmian trajectory perspective on strong field atomic processes*

Author

Xiao-Jun Liu and Xuan-Yang Lai

Subjects

Physics, Classical mechanics, Computer Science::Information Retrieval, Perspective (graphical), Physics::Atomic and Molecular Clusters, Trajectory, General Physics and Astronomy, Strong field, Physics::Atomic Physics

Abstract

The interaction of an atom with an intense laser field provides an important approach to explore the ultrafast electron dynamics and extract the information of the atomic and molecular structures with unprecedented attosecond temporal and angstrom spatial resolution. To well understand the strong field atomic processes, numerous theoretical methods have been developed, including solving the time-dependent Schrödinger equation (TDSE), classical and semiclassical trajectory method, quantumS-matrix theory within the strong-field approximation,etc. Recently, an alternative and complementary quantum approach, called Bohmian trajectory theory, has been successfully used in the strong-field atomic physics and an exciting progress has been achieved in the study of strong-field phenomena. In this paper, we provide an overview of the Bohmian trajectory method and its perspective on two strong field atomic processes,i.e., atomic and molecular ionization and high-order harmonic generation, respectively.

Published

2020

3. Enhancement of photoacoustic tomography in the tissue with speed-of-sound variance using ultrasound computed tomography

Author

Cheng Ren-Xiang, Chao Tao, and Xiao-Jun Liu

Subjects

medicine.medical_specialty, Materials science, medicine.diagnostic_test, Image quality, business.industry, Ultrasound, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, General Physics and Astronomy, Photoacoustic imaging in biomedicine, Computed tomography, Variance (accounting), Imaging quality, Speed of sound, Photoacoustic tomography, medicine, Medical physics, business, ComputingMethodologies_COMPUTERGRAPHICS, Biomedical engineering

Abstract

The speed-of-sound variance will decrease the imaging quality of photoacoustic tomography in acoustically inhomogeneous tissue. In this study, ultrasound computed tomography is combined with photoacoustic tomography to enhance the photoacoustic tomography in this situation. The speed-of-sound information is recovered by ultrasound computed tomography. Then, an improved delay-and-sum method is used to reconstruct the image from the photoacoustic signals. The simulation results validate that the proposed method can obtain a better photoacoustic tomography than the conventional method when the speed-of-sound variance is increased. In addition, the influences of the speed-of-sound variance and the fan-angle on the image quality are quantitatively explored to optimize the image scheme. The proposed method has a good performance even when the speed-of-sound variance reaches 14.2%. Furthermore, an optimized fan angle is revealed, which can keep the good image quality with a low cost of hardware. This study has a potential value in extending the biomedical application of photoacoustic tomography.

Published

2015

4. Effect of slow-solvent-vapour treatment on performance of polymer photovoltaic devices

Author

Zhi-Hui, Feng, primary, Yan-Bing, Hou, additional, Quan-Min, Shi, additional, Xiao-Jun, Liu, additional, and Feng, Teng, additional

Published

2010

5. Polymer solar cells based on a PEDOT:PSS layer spin-coated under the action of an electric field

Author

Zhi-Hui, Feng, primary, Yan-Bing, Hou, additional, Quan-Min, Shi, additional, Li-Fang, Qin, additional, Yan, Li, additional, Lei, Zhang, additional, Xiao-Jun, Liu, additional, Feng, Teng, additional, Yong-Sheng, Wang, additional, and Rui-Dong, Xia, additional

Published

2010

6. Tunneling between double wells of atom in crossed electromagnetic fields

Author

Li, Shen, primary, Lei, Wang, additional, Hai-Feng, Yang, additional, Xiao-Jun, Liu, additional, and Hong-Ping, Liu, additional

Published

2009

7. Scaled-energy spectroscopy of a | M | = 1 Rydberg barium atom in an electric field

Author

Lei, Wang, primary, Wei, Quan, additional, Li, Shen, additional, Hai-Feng, Yang, additional, Ting-Yun, Shi, additional, Xiao-Jun, Liu, additional, Hong-Ping, Liu, additional, and Ming-Sheng, Zhan, additional

Published

2009

8. Finite element analysis of three-dimensional laser-induced transient thermal grating in diamond/ZnSe system

Author

Ying, Cheng, primary, Qiao-Jian, Huang, additional, and Xiao-Jun, Liu, additional

Published

2008

9. Enormous enhancement of electric field in active gold nanoshells.

Author

Shu-Min, Jiang, Da-Jian, Wu, Xue-Wei, Wu, and Xiao-Jun, Liu

Subjects

SERS spectroscopy, ELECTRIC field strength, GOLD nanoparticles, MIE scattering, SINGLE molecule detection

Abstract

The electric field enhancement properties of an active gold nanoshell with gain material inside have been investigated by using Mie theory. As the gain coefficient of the inner core increases to a critical value, a super-resonance appears in the active gold nanoshell, and enormous enhancements of the electric fields can be found near the surface of the particle. With increasing shell thickness, the critical value of the gain coefficient for the super-resonance of the active gold nanoshell first decreases and then increases, and the corresponding surface enhanced Raman scattering (SERS) enhancement factor (G factor) also first increases and then decreases. The optimized active gold nanoshell can be obtained with an extremely high SERS G factor of the order of 1019–1020. Such an optimized active gold nanoshell possesses a high-efficiency SERS effect and may be useful for single-molecule detection. [ABSTRACT FROM AUTHOR]

Published

2014

10. The Coulomb effect on a low-energy structure in above-threshold ionization spectra induced by mid-infrared laser pulses.

Author

Zhi-Yang, Lin, Ming-Yan, Wu, Wei, Quan, Xiao-Jun, Liu, Jing, Chen, and Ya, Cheng

Subjects

IONIZATION energy, INFRARED lasers, LASER pulses, SPECTRUM analysis, COULOMB potential

Abstract

We investigate the low-energy structure (LES) in the above-threshold ionization spectrum at a mid-infrared laser wavelength with a semiclassical model. Using a softened Coulomb potential (CP) and changing the softening parameter, we show that though the very low-energy structure (VLES) and high low-energy structure (HLES) are both due to the interaction between the ionic CP and the electron, the two structures have different physical mechanisms: the VLES can be attributed to the electron—ion Coulomb interaction at a rather small distance and the HLES is more likely to be ascribed to the electron—ion Coulomb interaction at a large distance. [ABSTRACT FROM AUTHOR]

Published

2014

11. Manipulated localized surface plasmon resonances in silver nanoshells coated with a spherical anisotropic layer.

Author

Shu-Min, Jiang, Da-Jian, Wu, Cheng Ying, and Xiao-Jun, Liu

Subjects

SURFACE plasmon resonance, SILVER nanoparticles, ANISOTROPY, SCATTERING (Physics), THICKNESS measurement, FIELD theory (Physics), WAVELENGTHS

Abstract

The influences of the anisotropy of the outer spherically anisotropic (SA) layer on the far-field spectra and nearfield enhancements of the silver nanoshells are investigated by using a modified Mie scattering theory. It is found that with the increase of the anisotropic value of the SA layer, the dipole resonance wavelength of the silver nanoshell first increases and then decreases, while the local field factor (LFF) reduces. With the decrease of SA layer thickness, the dipole wavelength of the silver nanoshell shows a distinct blue-shift. When the SA layer becomes very thin, the modulations of the anisotropy of the SA layer on the plasmon resonance energy and the near-field enhancement are weakened. We further find that the smaller anisotropic value of the SA layer is helpful for obtaining the larger near-field enhancement in the Ag nanoshell. The geometric average of the dielectric components of the SA layer has a stronger effect on the plasmon resonance energy of the silver nanoshell than on the near-field enhancement. [ABSTRACT FROM AUTHOR]

Published

2012

12. Bohmian trajectory perspective on strong field atomic processes.

Author

Xuan-Yang Lai and Xiao-Jun Liu

Subjects

*ATOMIC physics, *TIME-dependent Schrodinger equations, *QUANTUM theory, *S-matrix theory, *ATOMIC structure, *ATTOSECOND pulses

Abstract

The interaction of an atom with an intense laser field provides an important approach to explore the ultrafast electron dynamics and extract the information of the atomic and molecular structures with unprecedented attosecond temporal and angstrom spatial resolution. To well understand the strong field atomic processes, numerous theoretical methods have been developed, including solving the time-dependent Schrödinger equation (TDSE), classical and semiclassical trajectory method, quantum S-matrix theory within the strong-field approximation, etc. Recently, an alternative and complementary quantum approach, called Bohmian trajectory theory, has been successfully used in the strong-field atomic physics and an exciting progress has been achieved in the study of strong-field phenomena. In this paper, we provide an overview of the Bohmian trajectory method and its perspective on two strong field atomic processes, i.e., atomic and molecular ionization and high-order harmonic generation, respectively. [ABSTRACT FROM AUTHOR]

Published

2020

13. Orientation-dependent depolarization of supercontinuum in BaF2 crystal.

Author

Zi-Xi Li, Cheng Gong, Tian-Jiao Shao, Lin-Qiang Hua, Xue-Bin Bian, and Xiao-Jun Liu

Subjects

SUPERCONTINUUM generation, CRYSTAL orientation, FEMTOSECOND lasers, BARIUM fluoride, CRYSTALS, PLASMA production, MAGNETOHYDRODYNAMIC generators

Abstract

We present a systematic investigation of the depolarization properties of a supercontinuum accompanied with femtosecond laser filamentation in barium fluoride (BaF2) crystal. It is found that the depolarization of the supercontinuum depends strongly on the crystal orientations with respect to the incident laser polarization. At most crystal orientations, the depolarization of the supercontinuum rises with the increase of the input laser energies and finally saturates. While at 45°, the depolarization of the supercontinuum is not changed and keeps nearly negligible with the increase of the input laser energies. These peculiar depolarization properties of the supercontinuum can be ascribed to the orientation dependence of the cross-polarized wave (XPW) generation and ionization-induced plasma scattering in the BaF2 crystal. [ABSTRACT FROM AUTHOR]

Published

2020

14. Femtosecond enhancement cavity with kilowatt average power.

Author

Jin Zhang, Lin-Qiang Hua, Shao-Gang Yu, Zhong Chen, and Xiao-Jun Liu

Subjects

BREWSTER'S angle, HARMONIC generation, NOBLE gases, HOLES

Abstract

Femtosecond enhancement cavity (fsEC) has been proved to be a powerful tool in a diverse range of applications. Here, we report the recent progresses in building an fsEC on kilowatt level average power, with the aim of realization of intracavity high harmonic generation (HHG) and extension of the wavelength of femtosecond optical frequency comb from infrared (IR) to extreme ultraviolet (XUV). Upon mode-matching optimization and cavity length locking, an intracavity average power of 6.08 kW is reached and the corresponding buildup is 225. After introducing noble gas of Xe into the focus region, clear sign of plasma has been observed. The generated HHG is also coupled out by a sapphire plate placed at Brewsterʼs angle for the fundamental laser. Our work paves the way for the realization of an XUV comb. [ABSTRACT FROM AUTHOR]

Published

2019

15. Thermoacoustic-reflected focusing lens based on acoustic Bessel-like beam with phase manipulation.

Author

An-Ru Hou, Wen-Ting Gao, Jiao Qian, Hong-Xiang Sun, Yong Ge, Shou-Qi Yuan, Qiao-Rui Si, and Xiao-Jun Liu

Subjects

THERMOACOUSTICS, BESSEL beams, PHASED array antennas, THERMAL insulation, BANDWIDTHS

Abstract

We report the realization of broadband reflected acoustic focusing lenses based on thermoacoustic phased arrays of Bessel-like beams, in which the units of phase manipulation are composed of three rigid insulated boundaries and a thermal insulation film in air with different temperatures. Based on these units, we realize a reflected focusing lens which can focus reflected acoustic energy on a line, and its fractional bandwidth can reach about 0.29. In addition, we discuss the influences of the base angle of Bessel-like beam, the number of basic unit, and the variation of unit temperature on focusing performances in details. Furthermore, the reflected focusing lens for the cylindrical acoustic wave based on the Bessel-like beam is also demonstrated. The proposed focusing lens has the advantages of a broad working bandwidth, large focus size, and high robustness, which may provide possibilities for the design and application of acoustic lenses. [ABSTRACT FROM AUTHOR]

Published

2018

16. High-order harmonic generation in a two-color strong laser field with Bohmian trajectory theory.

Author

Yi-Yi Huang, Xuan-Yang Lai, and Xiao-Jun Liu

Subjects

HARMONIC generation, BOHMIAN mechanics, SCHRODINGER equation, SIMULATION methods & models, LASER pulses

Abstract

We theoretically study the high-order harmonic generation (HHG) in a two-color laser field using the Bohmian mechanics. Our results show that, for the case of a weak second-color laser field, the simulation of the HHG with only one central Bohmian trajectory is in a good agreement with the ab initio time-dependent Schrödinger equation (TDSE) results. In contrast, with the increase of the amplitude of the second-color laser field, the HHG spectra from the single central Bohmian trajectory deviate from the TDSE results more and more significantly. By analyzing the Bohmian trajectories, we find that the significant deviation is due to the fact that the central Bohmian trajectory leaves the core quickly in the two-color laser field with the breaking of inversion symmetry. Interestingly, we find that another Bohmian trajectory with different initial position, which keeps oscillating around the core, could qualitatively well reproduce the TDSE results. Furthermore, we study the HHG spectrum in a two-color laser field with inversion symmetry and find that the HHG spectrum in TDSE can be still well simulated with the central Bohmian trajectory. These results indicate that, similar to the case of one color laser field, the HHG spectra in a two-color laser field can be also reproduced with a single Bohmian trajectory, although the initial position of the trajectory is dependent on the symmetry of the laser field. Our work thus demonstrates that Bohmian trajectory theory can be used as a promising tool in investigating the HHG process in a two-color laser field. [ABSTRACT FROM AUTHOR]

Published

2018

17. Adaptive optimization on ultrasonic transmission tomography-based temperature image for biomedical treatment.

Author

Yun-Hao Zhu, Jie Yuan, Stephen Z Pinter, Oliver D Kripfgans, Qian Cheng, Xue-Ding Wang, Chao Tao, Xiao-Jun Liu, Guan Xu, and Paul L Carson

Subjects

FEVER, BREAST cancer treatment, TUMOR treatment, HILBERT-Huang transform, HILBERT transform

Abstract

Hyperthermia has proven to be beneficial to treating superficial malignancies, particularly chest wall recurrences of breast cancer. During hyperthermia, monitoring the time–temperature profiles in the target and surrounding areas is of great significance for the effect of therapy. An ultrasound-based temperature imaging method has advantages over other approaches. When the temperature around the tumor is calculated by using the propagation speed of ultrasound, there always exist overshoot artifacts along the boundary between different tissues. In this paper, we present a new method combined with empirical mode decomposition (EDM), similarity constraint, and continuity constraint to optimize the temperature images. Simulation and phantom experiment results compared with those from our previously proposed method prove that the EMD-based method can build a better temperature field image, which can adaptively yield better temperature images with less computation for assistant medical treatment control. [ABSTRACT FROM AUTHOR]

Published

2017

18. An acoustic Maxwell’s fish-eye lens based on gradient-index metamaterials.

Author

Bao-guo Yuan, Ye Tian, Ying Cheng, and Xiao-jun Liu

Subjects

ACOUSTIC lenses, MAXWELL equations, CRYSTALLINE lens, GRADIENT-index devices, METAMATERIALS

Abstract

We have proposed a two-dimensional acoustic Maxwell’s fish-eye lens by using the gradient-index metamaterials with space-coiling units. By adjusting the structural parameters of the units, the refractive index can be gradually varied, which is key role to design the acoustic fish-eye lens. As predicted by ray trajectories on a virtual sphere, the proposed lens has the capability to focus the acoustic wave irradiated from a point source at the surface of the lens on the diametrically opposite side of the lens. The broadband and low loss performance is further demonstrated for the lens. The proposed acoustic fish-eye lens is expected to have the potential applications in directional acoustic coupler or coherent ultrasonic imaging. [ABSTRACT FROM AUTHOR]

Published

2016

19. Manipulation of extraordinary acoustic transmission by a tunable bull's eye structure.

Author

Ji-Wei Wang, Ying Cheng, and Xiao-Jun Liu

Subjects

SOUND waves, FABRY-Perot resonators, WAVE diffraction, DIFFRACTION gratings, OPTICAL properties, METAMATERIALS, COMPUTER simulation

Abstract

Extraordinary acoustic transmission (EAT) has been investigated in a tunable bull's eye structure. We demonstrate that the transmission coefficient of acoustic waves can be modulated by a grating structure. When the grating is located at a distance of 0.5 mm from the base plate, the acoustic transmission shows an 8.77-fold enhancement compared to that by using a traditional bull's eye structure. When the distance increases to 1.5 mm, the transmission approaches zero, indicating a total reflection. Thus, we can make an efficient modulation of acoustic transmission from 0 to 877%. The EAT effects have been ascribed to the coupling of structure-induced resonance with the diffractive wave and the waveguide modes, as well as the Fabry-Perot resonances. As a potential application, the modulation of far-field collimation is illustrated in the proposed bull's eye structure. [ABSTRACT FROM AUTHOR]

Published

2014