In periodic systems of interacting electrons, Fermi and Luttinger surfaces refer to the locations within the Brillouin zone of poles and zeros, respectively, of the single-particle Green's function at zero energy and temperature. Such difference in analytic properties underlies the emergence of well-defined quasiparticles close to a Fermi surface, in contrast to their supposed non-existence close to a Luttinger surface, where the single-particle density-of-states vanishes at zero energy.
We here show that, contrary to such common belief, coherent quasiparticles
do exist also approaching a Luttinger surface in compressible interacting electron systems. Thermodynamic and dynamic properties of such quasiparticles
are just those of conventional ones. For instance, they yield well defined quantum oscillations
in Luttinger's surface and linear in temperature specific heat, which is striking given the vanishing density of states of physical electrons, but actually not uncommon in strongly correlated materials.