High-temperature Superconductivity Restrained by Orbital Hybridisation

The minimal ingredients to explain the essential physics of layered copper-oxide (cuprates) materials remains heavily debated. Effective low-energy single-band models of the copper oxygen orbitals are widely used because there exists no strong experimental evidence supporting multi-band structures. Here we report angle-resolved photoemission spectroscopy experiments on La-based cuprates that provide direct observation of a two-band structure. This electronic structure, qualitatively consistent with density functional theory, is parametrised by a two-orbital ($d_{x^2-y^2}$ and $d_{z^2}$) tight-binding model. We quantify the orbital hybridisation which provides an explanation for the Fermi surface topology and the proximity of the van-Hove singularity to the Fermi level. Our analysis leads to a unification of electronic hopping parameters for single layer cuprates. Hybridisation that restrains d-wave pairing is an important optimisation element for superconductivity.