860 likes | 882 Views
Explore the unique methods using vibrating aerogel resonators to measure superfluid density, phase diagrams, and gapless superfluidity in a zero-temperature regime. Uncover the sensitive thermometer capabilities and different phases of superfluidity.
E N D
Outline of talk • Superfluid 3He in aerogel at ULT, a dirty metric. • Background on the techniques of the vibrating aerogel resonator. • First simple experiment - measuring the superfluid density. • The magnetic field - temperature phase diagram. • Gapless superfluidity in aerogel. • * All experiments in the “zero temperature” regime where the normal fluid density is effectively nil.
Thus more quasiparticles scatter normally from front side. • Inverse at rear side (more quasiholes scatter). • This gives enormous force on the wire despite a “good vacuum” of excitations. • The force is proportional to the excitation density thus providing an extremely sensitive thermometer/ excitation density/ energy detector. • Frequency width/damping Df2 µ exp(-D/kT) • (or the damping measures the density of occupied states just above the gap).
This gives a very accurate temperature scale as the damping, Df2, is changing over many orders of magnitude
How does the device work? • It measures the superfluid density inside the aerogel but by an indirect method.
If the aerogel holds 100% superfluid then it is completely transparent. * Remember, at our temperatures the bulk liquid is 100% superfluid.
The frequency of the resonator is determined by the backflow. Therefore the frequency gives immediately the value of the superfluid density inside the aerogel. • The resonator looks like the poor man’s torsional oscillator but it works on a different principle – as well as being much simpler. • Expt. 3 The superfluid density.
The frequency of the resonator is determined by the backflow. Therefore the frequency gives immediately the value of the superfluid density inside the aerogel. • This can be thought of as the poor man’s torsional oscillator but in fact gives complimentary information – as well as being much simpler. • And we note that the superfluid density tells us that the critical temperature is depressed (rsÞ0), and that the value of rs is much less than 100%.
One thing we can immediately do with this resonator is distinguish between A phase and B phase since the superfluid densities in the two phases are completely different. • That means that we can use this simple device to map out the phase diagram at ultralow temperatures as a function of temperature and magnetic field. • The phase diagram probes the differences between the phases and thus any differential response of the two phases to magnetic fields. • Experiment 4. The T-B Phase diagram