This article reviews theoretical and experimental developments for one-dimensional Fermi
gases. Specifically, the experimentally realized two-component delta-function interacting …

Alkaline-earth and ytterbium cold atomic gases make it possible to simulate SU (N)-
symmetric fermionic systems in a very controlled fashion. Such a high symmetry is expected …

Recent experimental progress in controlling neutral group-II atoms for optical clocks, and in
the production of degenerate gases with group-II atoms has given rise to novel opportunities …

We investigate one-dimensional SU (N) Hubbard chains at zero temperature, which can be
emulated with ultracold alkaline-earth-metal atoms, by using the density matrix …

Large three-body loss rates in a three-component Fermi gas confined in an optical lattice
can dynamically prevent atoms from tunneling so as to occupy a lattice site with three atoms …

For over twenty years, ultra‐cold atomic systems have formed an almost perfect arena for
simulating different quantum many‐body phenomena and exposing their non‐obvious and …

We study the attractive SU (N) Hubbard model with particle-hole symmetry. The model is
defined on a bipartite lattice with the number of sites NA (NB) in the A (B) sublattice. We …

We show that a simple one-dimensional model of spinless fermions with pair hop**
displays a phase in which a Luttinger liquid of paired fermions coexists with a Luttinger …

We investigate possible realizations of exotic SU (N) symmetry-protected topological (SPT)
phases with alkaline-earth cold fermionic atoms loaded into one-dimensional optical lattices …

We investigate one dimensional attractive Fermi gases in spin-dependent optical lattices.
We show that three-body bound states—“trimers”—exist as soon as the two tunneling rates …