A Summary of Mass Flux Measurements in Solid 4He

Here we provide a summary and brief review of some of the work done with solid ⁴He at the University of Massachusetts Amherst below a sample pressure of 28?bar. The motivation for the work has been to attempt to pass ⁴He atoms through solid ⁴He without directly applying mechanical pressure to the solid itself. The specific technique chosen is limited to pressures near the melting curve and was initially designed to provide a yes/no answer to the question of whether or not it might be possible to observe such a mass flux. The thermo-mechanical effect and direct mass injection have been separately used to create chemical potential differences between two reservoirs of superfluid ⁴He connected to each other through superfluid-filled Vycor rods in series with solid ⁴He, which is in the hcp region of the phase diagram. The thermo-mechanical effect is a more versatile approach. And, in a particular symmetric application it is designed to provide a mass flux with little or no net increase in the density of the solid. Our observations, off but near the melting curve, have included: (1)?the presence of an increasing DC flux of atoms through the solid-filled cell with decreasing temperature below ≈650?mK and no flux above this temperature; (2)?the presence of a flux minimum and flux instability in the vicinity of 75–80?mK, with a flux increase at lower temperatures; (3)?the temperature dependence of the flux above 100?mK and the dependence of the flux on the net driving chemical potential difference provide interesting insights on the possible mechanism that leads to the flux above 100?mK. The most recent data suggest that whatever is responsible for the flux in solid ⁴He, at least for T>100?mK, may be an example of a Bosonic Luttinger liquid.