Transport in the emergent Bose liquid: bad metal, strange metal, and weak insulator, all in one system

Non-saturating high-temperature resistivity (“bad metal”), T-linear low-temperature resistivity (“strange metal”), and a crossover to activation-free growth of the resistivity in the low-temperature limit (“weak insulator”) are among the most exotic behaviors widely observed in many strongly correlated materials that defy the standard Fermi liquid description of solids. Here we investigate these puzzling behaviors by computing temperature-dependent optical conductivity of an emergent Bose liquid and find that it reproduces all the unexplained features of the experiments, including a featureless continuum and a well-known mid-infrared peak. Amazingly and with physically intuitive mechanisms, the corresponding doping- and temperature-dependent resistivity displays the bad metal and strange metal simultaneously and sometimes weak insulating behaviors as well. The unification of all these non-Fermi liquid behaviors under a single model strongly supports a new paradigm: The low-energy physics in a large class of strongly correlated materials may be dominated by a new quantum state of matter, namely the emergent Bose liquid.