Unveiling Hidden Physics in the 215-Kelvin Superconducting Calcium Hydride: Temperature, Quantum and Defect Effects

Temperature and quantum effects induce the structural complexity of condensed hydrogen, and therefore they are expected to impact nontrivially the structures of clathrate hydrides. Exemplified by clathrate calcium hydride, we show through ab initio (path-integral) molecular dynamics simulations that these effects are indeed pivotal at 100-200 GPa. The quantum equation of states derived at 300 K suggests that the synthesized samples in previous experiments were berthollide-like CaH$_{6-\delta}$, with the stoichiometric defect $\delta$ increasing smoothly during decompression. The change of composition provides an explanation for the experimental observation of positive pressure dependence of superconducting T$_c$ below 165 GPa. Furthermore, we find significant proton diffusion in CaH$_{6-\delta}$ at 150-300 K, with the diffusion coefficient reaching 10$^{-7}$ cm$^{2}$/s. This suggests a coexistence of superconductivity and proton diffusion in clathrate hydrides. Our findings underline the importance of temperature, quantum and defect effects to the understandings of the structure and pertinent physics in high-T$_c$ superconducting clathrate hydrides.