Exploring spin-orbital models with dipolar fermions in zigzag optical lattices
Physical Review B—Condensed Matter and Materials Physics, 2012•APS
Ultracold dipolar spinor fermions in zig-zag–type optical lattices can mimic spin-orbital
models relevant in solid-state systems, as transition-metal oxides with partially filled d levels,
with the interesting advantage of reviving the quantum nature of orbital fluctuations. We
discuss two different physical systems in which these models may be simulated, showing
that the interplay between lattice geometry and spin-orbital quantum dynamics produces a
wealth of novel quantum phases.
models relevant in solid-state systems, as transition-metal oxides with partially filled d levels,
with the interesting advantage of reviving the quantum nature of orbital fluctuations. We
discuss two different physical systems in which these models may be simulated, showing
that the interplay between lattice geometry and spin-orbital quantum dynamics produces a
wealth of novel quantum phases.
Ultracold dipolar spinor fermions in zig-zag–type optical lattices can mimic spin-orbital models relevant in solid-state systems, as transition-metal oxides with partially filled levels, with the interesting advantage of reviving the quantum nature of orbital fluctuations. We discuss two different physical systems in which these models may be simulated, showing that the interplay between lattice geometry and spin-orbital quantum dynamics produces a wealth of novel quantum phases.
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