Generation of Strong Fields to Study the Phase Transitions of Magnetized Warm Dense Matter

Warm dense matter is a regime where Fermi degenerate electrons take an important role in the macroscopic properties of a material. While recent experiments hinged us closer to better understanding the unmagnetized processes in such dense materials, their magnetized counterpart has been more difficult to study since kilo-Tesla order magnetic fields are required. Although there are examples of field compression generating such fields by compressing pre-magnetized targets, this approach uses a closed configuration, where a converging liner compresses the magnetic flux dynamically. The plasma produced to compress the field is so dense that the fast-heating laser beam required to form warm dense matter cannot penetrate where the field is the highest. In this paper, numerical simulations are used to show that magnetic field compression is also possible by shining the laser beams onto the inner surface of the target, rather than on the outer surface. This approach relies on field compression done by a low-density high-temperature plasma, rather than a high-density low-temperature plasma, used in the more conventional approach. With this novel configuration, the region of the large magnetic field is now mostly free of plasma so the heating beam can reach the sample, located where the magnetic field is the strongest.