Wilson ratio

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The Wilson ratio of a metal is the dimensionless ratio of the zero-temperature magnetic susceptibility and the coefficient of the linear temperature term in the electronic specific heat. The relative—value of the Wilson ratio, compared to the Wilson ratio for the non-interacting Fermi-gas, can provide insight into the types of interactions present.

The Wilson ratio can be used to characterize strongly correlated Fermi liquids.^[1] The Fermi liquid theory explains the behaviour of metals at very low temperatures. Two important features of a metal which obey this theory are:

1. At temperatures much below the Fermi temperature the specific heat is proportional to the temperature
2. The magnetic susceptibility is independent of temperature

Both of these quantities, however, are proportional to the electronic density of states at Fermi energy. Their ratio is a dimensionless quantity called the Wilson (or the Sommerfeld - Wilson) Ratio,^[2] defined as:

R_w = 4π²k_B²Tχ_p/3μ₀(g_eμ_B)²C_elec

After substituting the values of χ_p (Pauli susceptibility) and C_elec (electronic contribution to specific heat), obtained using Sommerfeld theory, the value obtained for R_w in the case of a free electron gas is 1.

In the case of real Fermi-liquid metals, the ratio can differ significantly from 1. The difference arises due to electron - electron interactions within the system. These tend to change the effective electronic mass, which affects both specific heat and magnetic susceptibility. Whether or not this increase in both is given by the same multiplicative factor is shown by the Wilson ratio. In some cases, electron - electron interactions give rise to an additional increase in susceptibility.

The converse is also true, i.e. a deviation of experimental value of R_w from 1 indicates strong electronic correlations.^[3]

• Fermi liquid theory
• Heavy fermion
• Kadowaki-Woods ratio
• Wiedemann–Franz law

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