Collective P-Wave Orbital Dynamics of Ultracold Fermions.

We introduce a protocol to observe p-wave interactions in ultracold fermionic atoms loaded in a three-dimensional optical lattice. Our scheme uses specific motionally excited band states to form an orbital subspace immune to band relaxation. A laser dressing is applied to reduce the differential kinetic energy of the orbital states and make their dispersion highly isotropic. When combined with a moderate increase of the scattering volume by a Feshbach resonance, the effect of p-wave interactions between the orbitals can be observed from the system dynamics on realistic timescales. By considering the evolution of ferromagnetic product states, we further explore parameter regimes where collective enhancement of p-wave physics facilitated by a many-body gap enables us to map the complex extended Fermi-Hubbard Hamiltonian of the system to a simple one-axis twisting model. Experimental protocols to probe the resulting many-body dynamics, state preparation, and detection are presented, including the effects of particle loss, spin-orbit coupling, and doping.