Anode Shape and Hollow Effects on Neutron Yield in a 4.4 kJ Dense Plasma Focus Device

Veronica Eudave; Eric Hahn; Swarvanu Gosh; Jeff Narkis; Fabio Conti; Farhat N Beg

Anode Shape and Hollow Effects on Neutron Yield in a 4.4 kJ Dense Plasma Focus Device

POSTER

Abstract

Dense Plasma Focus (DPF) is a Z-pinch configuration that consists of coaxial electrodes that guide a dynamic plasma sheath along the anode, resulting in a hot dense pinch near the anode tip. A DPF can produce X-rays, energetic ions, and high intensity fast neutron pulses depending on the fill gas. We report on experiments using a 4.4 kJ Mather-type DPF exploring the role of anode geometry with a focus on curved and flat anodes with and without a hollow center, such as highlighted in recent studies^1,2. The dynamics of the collapsing plasma are described in terms of the contribution of anode geometry and deuterium pressure. The resulting pinch structure is quantified optically and neutron yields, as measured by a Be-activation detector, will be described.

1. A. Link et al., AIP Conf. Proc. 1639, 23 (2014)

2. B. H. Shaw et al., J. Appl. Phys. 124, 233301 (2018)

Presenters

Veronica Eudave

University of California, San Diego

Authors

Veronica Eudave

University of California, San Diego
Eric Hahn

University of California San Diego, University of California, San Diego
Swarvanu Gosh

University of California San Diego, University of California, San Diego
Jeff Narkis

University of California San Diego, University of California, San Diego
Fabio Conti

University of California, San Diego, University of California San Diego
Farhat N Beg

University of California San Diego, University of California, San Diego, Center for Energy Research,University of California, San Diego, USA.