Bosonic metal states in crystalline iron-based superconductors at the two-dimensional limit

The nature of the anomalous metal, one of the quantum ground states of two-dimensional (2D) bosonic systems, remains a major puzzle even after several decades of study. The main characteristic of an anomalous metal is the saturation of the low-temperature resistance at a value far smaller than that predicted by the Drude formula. This calls into question whether the conventional understanding of metals is applicable to bosonic cases. Here, we report two types of bosonic metal states in ultrathin crystalline FeSe films grown on SrTiO3, where the 2D high-temperature superconductivity is confined at the interface. Our experiments are performed on pristine FeSe films and FeSe films with a triangular array of nano-holes. In pristine FeSe films, the bosonic anomalous metal state emerges at a high temperature (around 20 K), higher than all previous observations. In stark contrast, in nanopatterned FeSe films, the characteristic temperature of the anomalous metal state is considerably suppressed. In both types of FeSe films, we observe a linear-in-temperature (T-linear) resistance below onset temperature for superconductivity. Interestingly, the extremely large slope of this T-linear resistance, suppressed Hall coefficient and clear h/2e quantum oscillations reveal the bosonic nature of the T-linear resistance, indicating a bosonic strange metal. Our discovery of the high-temperature anomalous metal state and the bosonic strange metal state in the 2D limit motivates further investigations aimed at unraveling the dissipation mechanism in bosonic metal states.