Study of the structure of exploding flat foils at superhigh current density.

We have investigated the features produced in flat metal foils as a result of nanosecond explosions and phase transitions at current densities of (0.1-2) ⋅ 109 A/cm². Thin foils made of aluminum, copper, nickel, and titanium, with thicknesses of 1-15 µm, were tested. The exploded foil structure was studied using X-pinch radiography and laser shadow imaging. Al, Ti, and Cu (5 and 7 µm thick) foils had an initial two-dimensional structure. At the same time, no apparent structure was registered in 1 µm Cu and 5 µm Ni foils. Experiments on generators with different output parameters have shown that the dominant structures that developed in the explosion are either cracks or bubbles and may depend on the orientation of the initial structure in the thin foil with respect to the current direction. In addition, the energy deposited in the foil differs by a factor of about 1.5 for the orthogonal vs parallel current and initial foil structure directions. [ABSTRACT FROM AUTHOR]