Switching on a superfluid

But while these phase transitions are well understood in the case of water, much less is known about the dynamics when a system goes from being a normal fluid to a superfluid, which can flow with zero friction, ie without losing any energy.

A new Swinburne study observing transition of an atomic gas from normal fluid to superfluid provides new insights into the formation of these remarkable states, with a view to future, superfluid-based, quantum technologies, such as ultra-low energy electronics.

Superfluid formation was seen to involve a number of different timescales, associated with different dynamical processes that take place upon crossing the phase boundary.

UNDERSTANDING DYNAMIC TRANSITIONS, TOWARDS FUTURE TECHNOLOGIES

As a nonequilibrium, dynamic process, phase transitions are challenging to understand from a theoretical perspective, inside these fascinating and potentially useful states of matter.

Such non-equilibrium phenomena in many-body quantum systems involves a complex interplay of correlations spanning vastly different spatio-temporal scales. Access to the full dynamics in most materials can be prohibited by the ultrashort timescales.

Future technologies based on quantum states such as superfluids or superconductors will need to be 'switched' (on/off), so understanding how systems evolve after switching answers important basic questions, such as how fast such devices can operate.

Forming a superfluid involves the correlated motion of the many microscopic constituents within a large collection of quantum-mechanical particles.

"Dilute gases of ultracold atoms however, allow measurements of real-time dynamics on accessible timescales," explains lead author Dr Paul Dyke (Swinburne).

"Here we use an ultracold gas of strongly interacting fermionic atoms (ie, a Fermi gas), to study how the correlations required to form a superfluid build up after a sudden quench of the interactions. This takes the system out of equilibrium."

"By measuring the subsequent dynamics as the system returns to equilibrium we can resolve the different timescales involved, for the various correlations to build up. These timescales depend on the corresponding length scales, with short range correlations and pair formation developing quickly, while the overall momentum distribution can take several orders of magnitude longer to reach equilibrium."

The new experiment showed that:

• Formation and condensation of fermion pairs can take place on very different timescales, depending on the speed of the quench.
• The contact parameter is seen to respond very quickly to changes in the interaction strength, indicating that short-range correlations, evolve far more rapidly than the long-range correlations necessary to form a Bose-Einstein condensate of atom pairs.

The contact parameter quantifies the likelihood of finding two atoms in very close proximity to each other, and is strongly enhanced when atoms form pairs.