Marginal Fermi Liquid behaviour from charge density fluctuations in cuprates

Besides the mechanism responsible for high critical temperature superconductivity, the grand unresolved issue of the cuprates is the occurrence of a "strange" metallic state above the so-called pseudogap temperature $T^*$. Even though such state has been successfully described within a phenomenological scheme, the so-called Marginal Fermi Liquid (MFL) theory, a microscopic explanation is still missing. However, recent resonant inelastic X-ray scattering experiments on Nd$_{1+x}$Ba$_{2-x}$Cu$_3$O$_{7-\delta}$ and YBa$_2$Cu$_3$O$_{7-\delta}$ films identified a new class of charge density fluctuations (CDFs) characterized by low characteristic energies and very short correlation lengths. These CDFs are present over a very wide region of the temperature-vs-doping phase diagram and extend well above $T^*$. We investigated the consequences of CDFs on the electronic and transport properties and found that they can be used to explain the MFL phenomenology. Therefore, charge density fluctuations are likely the long-sought microscopic mechanism underlying the peculiarities of the normal state of cuprates.