Your search keyword '"Guo, Jiewei"' showing total 4 results

1. A Simulation of Air Lasing Seeded by an External Wave in a Femtosecond Laser Filament.

Author

Zeng, Tao, Gui, Ya, Yi, Yuliang, Li, Nan, Zhang, Zhi, Guo, Jiewei, Shang, Binpeng, and Guo, Lanjun

Subjects

FIBERS, LASER beams, ANGULAR distribution (Nuclear physics), PLANE wavefronts, ACTIVE medium, REMOTE sensing, FEMTOSECOND lasers

Abstract

Air lasers induced by femtosecond laser filaments play an important role in remote sensing applications. Few studies have been dedicated to the spatial distribution of external-seeded air laser radiation in the laser filament based on the numerical simulation method, which can pave the way to understanding the mechanism of the external-seeded air lasing process during filamentation. In this study, numerical simulations of the propagation of an air laser seeded by an external plane wave with a wavelength of 391 nm during femtosecond laser filamentation were performed. The results indicated that the air laser's beam intensity distribution varies from a ring pattern to a donut pattern when the filament length and nitrogen ion density are raised as a result of the defocusing and lasing effects of the filament plasma. Here, the ring pattern is formed by several thin rings, while the donut pattern refers to a notably thicker, ring-like structure. In addition, it has been demonstrated that the air laser's beam power would increase exponentially versus the filament length and the nitrogen ion density. The knowledge about the angular distribution of air lasing could be important for optimizing the detection geometry of the LIDAR setup, including the view angle and the size of the collecting optical component. [ABSTRACT FROM AUTHOR]

Published

2023

2. Investigation of Focusing Properties on Astigmatic Gaussian Beams in Nonlinear Medium.

Author

Tao, Shishi, Xue, Jiayun, Guo, Jiewei, Zhao, Xing, Zhang, Zhi, Lin, Lie, and Liu, Weiwei

Subjects

GAUSSIAN beams, ASTIGMATISM, ACOUSTIC intensity, ASTIGMATISM (Optics), OPTICAL aberrations, REMOTE sensing

Abstract

Ultra-short laser filamentation has been intensively studied due to its unique optical properties for applications in the field of remote sensing and detection. Although significant progress has been made, the quality of the laser beam still suffers from various optical aberrations during long-range transmission. Astigmatism is a typical off-axis aberration that is often encountered in the off-axis optical systems. An effective method needs to be proposed to suppress the astigmatism of the beam during filamentation. Herein, we numerically investigated the impact of the nonlinear effects on the focusing properties of the astigmatic Gaussian beams in air and obtained similar results in the experiment. As the single pulse energy increases, the maximum on-axis intensity gradually shifted from the sagittal focus to the tangential focus and the foci moved forward simultaneously. Moreover, the astigmatism could be suppressed effectively with the enhancement of the nonlinear effects, that is, the astigmatic difference and the degree of beam distortion were both reduced. Through this approach, the acoustic intensity of the filament (located at the tangential focal point) increased by a factor of 22.8. Our work paves a solid step toward the practical applications of the astigmatism beam as the nonlinear lidar. [ABSTRACT FROM AUTHOR]

Published

2022

3. Beam Wander Restrained by Nonlinearity of Femtosecond Laser Filament in Air.

Author

Guo, Jiewei, Sun, Lu, Liu, Jinpei, Shang, Binpeng, Tao, Shishi, Zhang, Nan, Lin, Lie, and Zhang, Zhi

Subjects

*ATMOSPHERIC turbulence, *FIBERS, *REMOTE sensing, *FEMTOSECOND lasers, *TURBULENCE, *STANDARD deviations

Abstract

The filamentation process under atmospheric turbulence is critical to its remote-sensing application. The effects of turbulence intensity and location on the spatial distribution of femtosecond laser filaments in the air were studied. The experimental results show that the nonlinear effect of the filament can restrain the beam wander. When the turbulence intensity was 3.31 × 10 − 13   cm − 2 / 3 , the mean deviation of the wander of the filament center was only 27% of that of the linear transmitted beam. The change in turbulence location would lead to a change in the standard deviation of the beam centroid drift. Results also show that the filament length would be shortened, and that the filament would end up earlier in a turbulent environment. Since the filamentation-based LIDAR has been highly expected as an evolution multitrace pollutant remote-sensing technique, the study promotes our understanding of how turbulence influences filamentation and advances atmospheric remote sensing by applying a filament. [ABSTRACT FROM AUTHOR]

Published

2022

4. Manipulation of Long-Distance femtosecond laser Filamentation: From physical model to acoustic diagnosis.

Author

Shang, Binpeng, Qi, Pengfei, Guo, Jiewei, Zhang, Zhi, Guo, Lanjun, Chu, Chunyue, Liu, Jinpei, Kosareva, Olga G., Zhang, Nan, Lin, Lie, and Liu, Weiwei

Subjects

*ACOUSTIC models, *FEMTOSECOND pulses, *FOCAL length, *REMOTE sensing, *FEMTOSECOND lasers, *FIBERS

Abstract

• Acoustic method was adopted to quantitatively measure the long-distance filamentation. • A simple physical model was presented to analyze the spatial distribution of filament. • The onset and length of filament can be conveniently obtained from the model. • The increase of the filament length can be obtained for longer pulse with more energy. The promising application of femtosecond laser filamentation in atmospheric remote sensing brings imperative demand for diagnosing and controlling the spatiotemporal dynamics of long-distance filamentation. Here, the acoustic method was adopted to quantitatively diagnose the long-distance filamentation of femtosecond pulses manipulated by energy and temporal domain. The onset and length of filament can be conveniently obtained from a simple analytic formula based on reasonable approximation and further demonstrated by the experimental results. The influence of pulse energy and initial pulse chirp under three different focal lengths (∼10 m, 20 m, and 30 m) on the filamentation in the air were studied experimentally. These findings provide a guiding significance for the optimal control of the long-distance propagation of filament, thereby laying a firm foundation for femtosecond laser-based atmospheric remote sensing. [ABSTRACT FROM AUTHOR]

Published

2023