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Fermi liquid

Fermi liquid theory describes the generic physical properties which a collection of interacting fermions assumes (under certain conditions). In particular, it explains why the behaviour of interacting fermions may be (qualitatively) very similar to the behaviour of a Fermi gas (i.e. non-interacting fermions), in contrast to naive expectation. It also explains the quantitative differences. It was introduced by the russian physicist Lev Davidovich Landau in 1956. In particular, the electrons in a normal metal form a Fermi liquid, as well as the atoms of liquid He-3 (He-3 is an isotope of Helium, with 2 protons, 1 neutron and 2 electrons per atom. This makes an odd number of fermions inside the atom, such that the complete atom itself is also a fermion).

Loosely speaking, the following conditions are usually to be fulfilled in order to have a Fermi liquid: The system of interacting fermions is cooled to low-enough temperatures, the interaction between them is not too strong and the system is translationally invariant (such that momentum is conserved).

The Fermi liquid is qualitatively analogous to the non-interacting Fermi-gas, in the following sense: The system's dynamics and thermodynamics at low excitation energies and temperatures may be described by substituting for the non-interacting fermions so-called "quasi-particles", each of which carries the same spin, charge and momentum as the original particles. Physically these may be thought of as being particles whose motion is disturbed by the surrounding particles and which themselves perturb the particles in their vicinity. Each many-particle excited state of the interacting system may be described by listing all occupied momentum states, just as in the non-interacting system. As a consequence, quantities such as the heat capacity of the Fermi liquid behave qualitatively in the same way as in the Fermi gas (e.g. the heat capacity rises linearly with temperature).

However, the following differences to the non-interacting Fermi gas arise: