Strongly
interacting Fermi gases
Martin Zwierlein
MIT-Harvard
Center for Ultracold Atoms, Research Laboratory of Electronics, and
Department
of Physics,
Massachusetts Institute of Technology, Cambridge, Massachusetts 02139,
US
Fermions,
particles with half-integer spin like the electron, proton and neutron,
obey the Pauli principle: They cannot share one and the same quantum
state. This “anti-social” behavior is directly observed in experiments
with ultracold gases of fermionic atoms: Pauli blocking in momentum
space for a free Fermi gas, and in real space in gases confined to an
optical lattice. When fermions interact, new, rather “social” behavior
emerges, i.e. hydrodynamic flow, superfluidity and magnetism. The
interplay of Pauli’s principle and strong interactions poses great
difficulties to our understanding of complex Fermi systems, from nuclei
to high-temperature superconducting materials and neutron stars. I will
describe experiments on atomic Fermi gases where interactions become as
strong as allowed by quantum mechanics – the unitary Fermi gas,
fermions immersed in a Bose gas and the Fermi-Hubbard lattice gas.
Sound and heat transport distinguish collisionally hydrodnamic from
superfluid flow, while spin transport reveals the underlying mechanism
responsible for quantum magnetism.