Your search keyword '"Xiao-Hu Yang"' showing total 2 results

1. High-flux low-divergence positron beam generation from ultra-intense laser irradiated a tapered hollow target.

Author

Jian-Xun Liu, Yan-Yun Ma, Jun Zhao, Tong-Pu Yu, Xiao-Hu Yang, Long-Fei Gan, Guo-Bo Zhang, Jian-Feng Ya, Hong-Bin Zhuo, Jin-Jin Liu, Yuan Zhao, and Shigeo Kawata

Subjects

MAGNETIC flux, PARTICLES (Nuclear physics), POSITRON beams, POSITRONS, LASER pulses, ELECTRIC fields

Abstract

By using two-dimensional particle-in-cell simulations, we demonstrate high-flux dense positrons generation by irradiating an ultra-intense laser pulse onto a tapered hollow target. By using a laser with an intensity of 4 ×1023W/cm², it is shown that the Breit-Wheeler process dominates the positron production during the laser-target interaction and a positron beam with a total number >1015 is obtained, which is increased by five orders of magnitude than in the previous work at the same laser intensity. Due to the focusing effect of the transverse electric fields formed in the hollow cone wall, the divergence angle of the positron beam effectively decreases to ~15° with an effective temperature of ~674 MeV. When the laser intensity is doubled, both the positron flux (>1016) and temperature (963 MeV) increase, while the divergence angle gets smaller (~13°). The obtained high-flux low-divergence positron beam may have diverse applications in science, medicine, and engineering. [ABSTRACT FROM AUTHOR]

Published

2015

2. Enhanced electron injection in laser-driven bubble acceleration by ultra-intense laser irradiating foil-gas targets.

Author

Guo-Bo Zhang, Yan-Yun Ma, Han Xu, Hafz, Nasr A. M., Xiao-Hu Yang, Min Chen, Tong-Pu Yu, De-Bin Zou, Jian-Xun Liu, Jian-Feng Yan, Hong-Bin Zhuo, Long-Fei Gan, Li-Chao Tian, Fu-Qiu Shao, Yan Yin, and Kawata, S.

Subjects

ELECTRON accelerators, BUBBLES, LASER beams, TARGETS (Nuclear physics), LASER pulses, ELECTRON beams

Abstract

A scheme for enhancing the electron injection charge in a laser-driven bubble acceleration is proposed. In this scheme, a thin foil target is placed in front of a gas target. Upon interaction with an ultra-intense laser pulse, the foil emits electrons with large longitudinal momenta, allowing them to be trapped into the transmitted shaped laser-excited bubble in the gaseous plasma target. Twodimensional particle-in-cell simulation is used to demonstrate this scheme, and an electron beam with a total electron number of 4.21 × 108 μm-1 can be produced, which is twice the number of electrons produced without the foil. Such scheme may be widely used for applications that require high electron yields such as positron and gamma ray generation from relativistic electron beams interacting with solid targets. [ABSTRACT FROM AUTHOR]

Published

2015