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Efficient energy transition from kinetic to internal energy in supersonic collision of high-density plasma jets from conical implosions

Zhe Zhang, Xiao-Hui Yuan, Yihang Zhang, Hao Liu, Ke Fang, Cheng-Long Zhang, Zhengdong Liu, Xu Zhao, Quan-Li Dong, Gaoyang Liu, Yu Dai, Hao-Chen Gu, Yutong Li, Jian Zheng, Jiayong Zhong, Jie Zhang

2022Acta Physica Sinica20 citationsDOIOpen Access PDF

Abstract

A collision of supersonic jets in the double-cone ignition scheme is realized experimentally. With a very high deceleration, the supersonic jets merge into a high density plasma core, which will be further fast heated to ignition condition. Both the density and temperature of the plasma core are increased due to nearly 100% of kinetic energy of the jets converted into the internal energy. Some diagnostic tools are used to characterize the plasma, including X-ray Thomson scattering, hard X-ray monochromatic backlighting, X-ray streak imaging and framing imaging. The density of the supersonic jet arrive at about 5.5–8 g/cm<sup>3</sup>. During colliding, a stagnation phase lasts about 200 ps, and the maximum density of the plasma core is increased to (46 ± 24) g/cm<sup>3</sup>. By analyzing the velocity and temperature before and after colliding, it is found that 90% of the kinetic energy is converted into thermal energy.

Topics & Concepts

Supersonic speedPlasmaKinetic energyAtomic physicsPhysicsPlasma diagnosticsDense plasma focusMonochromatic colorInternal energyNuclear physicsOpticsMechanicsQuantum mechanicsLaser-Plasma Interactions and DiagnosticsComputational Fluid Dynamics and AerodynamicsParticle Dynamics in Fluid Flows
Efficient energy transition from kinetic to internal energy in supersonic collision of high-density plasma jets from conical implosions | Litcius