W. S. Zhang scite author profile

A novel double cone funnel target design aiming at efficiently guiding and focusing fast electron beams produced in high intensity (>1019 W/cm2) laser-solid interactions is investigated via two-dimensional particle-in-cell simulations. The forward-going fast electron beams are shown to be directed and focused to a smaller size in comparison with the incident laser spot size. This plasma funnel attached on the cone target guides and focuses electrons in a manner akin to the control of liquid by a plastic funnel. Such device has the potential to add substantial design flexibility and prevent inefficiencies for important applications such as fast ignition. Two reasons account for the collimation of fast electron beams. First, the sheath electric fields and quasistatic magnetic fields inside the vacuum gap of the double cone provide confinement of the fast electrons in the laser-plasma interaction region. Second, the interface magnetic fields inside the beam collimator further guide and focus the fast electrons during the transport. The application of this technique to cone-guided fast ignition is considered, and it is shown that it can enhance the laser energy deposition in the compressed fuel plasma by a factor of 2 in comparison with the single cone target case.

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The formation and dissipation of electrostatic shock waves: the role of ion–ion acoustic instabilities

Zhang

Cai

Zhu

2018

Plasma Phys. Control. Fusion

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The role of ion-ion acoustic instabilities in the formation and dissipation of collisionless electrostatic shock waves driven by counter-streaming supersonic plasma flows has been investigated via two-dimensional particle-in-cell simulations. The nonlinear evolution of unstable waves and ion velocity distributions has been analyzed in detail. It is found that for electrostatic shocks driven by moderate-velocity flows, longitudinal and oblique ion-ion acoustic instabilities can be excited in the downstream and upstream regions, which lead to thermalization of the transmitted and reflected ions, respectively. For high-velocity flows, oblique ion-ion acoustic instabilities can develop in the overlap layer during the shock formation process and impede the shock formation.

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Anomalous mix induced by a collisionless shock wave in an inertial confinement fusion hohlraum

Yan¹,

Cai²,

Zhang³

et al. 2019

Nucl. Fusion

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The anomalous mix at the high-Z and low-Z plasma interfaces in an inertial confinement fusion hohlraum is a current topic of interest. The mechanism for such an anomalous mix in the interpenetration layer at the high-Z and low-Z plasma interface and its effects on the laser plasma instabilities have been investigated by particle-in-cell simulations. It is found that a diffusion-driven collisionless shock wave can be generated from an initially sharp high-Z and low-Z plasma interface with total pressure balance and constant temperature in the laser propagation channel. This purely electrostatic shock wave propagates into the high-Z plasma and leads to mix of different species of ions which is significantly faster than a classical mix in the presence of the large electric field. The mix layer width, measured as a separation distance affected by the shock, grows as δd ∝ t α , where α ∼ 1. The effect of the anomalous mix on the linear growth rate of laser plasma instabilities is evaluated.

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Full particle-in-cell simulation of the formation and structure of a collisional plasma shock wave

Zhang

Cai

et al. 2021

Phys. Rev. E

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W. S. Zhang

Enhanced energy coupling for indirect-drive fast-ignition fusion targets

Guiding and focusing of fast electron beams produced by ultra-intense laser pulse using a double cone funnel target

The formation and dissipation of electrostatic shock waves: the role of ion–ion acoustic instabilities

Anomalous mix induced by a collisionless shock wave in an inertial confinement fusion hohlraum

Full particle-in-cell simulation of the formation and structure of a collisional plasma shock wave

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