Non-{{Fermi}}-Liquid Behaviour in Magnetic d- and f-Electron Systems

A growing number of metals have been found to show systematic deviations from the predictions of Landau Fermi-liquid theory. The most straightforward examples are magnetic metals in which the Curie (TC) or Néel (TN) temperature has been suppressed to 0 K by the application of hydrostatic pressure. Such systems are discussed here within a spin fluctuation framework which provides quantitatively accurate descriptions of the d-electron systems MnSi and ZrZn2 near their `quantum critical points', but which appears to be less successful (in its simplest form) in antiferromagnetic f-electron systems, particularly CePd2Si2, which at its critical pressure has a resistivity of the form $\Deltåho$ $\propto$ T1.2 = 0.1 over a temperature range extending from around 40 K to below 1 K. CeNi2Ge2, which is believed to be close to a quantum critical point at ambient pressure, shows similar behaviour. CeIn3, CePd2Si2 and CeNi2Ge2 exhibit superconductivity, in the first two cases limited to a narrow region near the critical pressure, making these the first unambiguous examples of magnetically mediated superconductivity.     «

A growing number of metals have been found to show systematic deviations from the predictions of Landau Fermi-liquid theory. The most straightforward examples are magnetic metals in which the Curie (TC) or Néel (TN) temperature has been suppressed to 0 K by the application of hydrostatic pressure. Such systems are discussed here within a spin fluctuation framework which provides quantitatively accurate descriptions of the d-electron systems MnSi and ZrZn2 near their `quantum critical points', b...     »