Generation Of Highly Symmetric, Cylindrically Convergent Shockwaves In Water

We report on pulsed power driven, exploding copper wire array experiments conducted to generate cylindrical convergent shockwaves in water employing mu s risetime currents > 550 kA in amplitude and with stored energies of > 15 kJ-a substantial increase over previous results. The experiments were carried out on the recently constructed Mega-Ampere-Compression-and-Hydrodynamics facility at Imperial College London in collaboration with colleagues of Technion, Israel. 10 mm diameter arrays consisting of 60 x 130 mu m wires were utilized, and the current and voltage diagnostics of the load region suggested that similar to 8 kJ of energy was deposited in the wires (and the load region close to the wires) during the experiments, resulting in the formation of dense, highly resistive plasmas that rapidly expanded driving the shockwaves in water. Laser-backlit framing images of the shockfront were obtained at radii <0.25mm for the first time, and there was strong evidence that even at radii <0.1mm this front remains stable, resulting in a convergence ratio of > 50:1. Framing images and streak photographs showed that the velocity of the shockwave reached similar to 7.5 km s(-1) at 0.1 mm from the axis. 2D hydrodynamic simulations that match the experimentally obtained implosion trajectory suggest that pressures > 1 Mbar are produced within 10 mu m of the axis along with water densities of 3gcm(-3) and temperatures of many 1000 s of Kelvin. Under these conditions, Quotidian Equation of State suggests that a strongly coupled plasma with an ionization fraction of similar to 0.7 would be formed. The results represent a "stepping stone" in the application of the technique to drive different material samples into high pressure, warm dense matter regimes with compact, university scale generators, and provide support in scaling the technique to multi-mega ampere currents. Published by AIP Publishing.