In-situ strain-tuning of the metal-insulator-transition of Ca2RuO4 in angle-resolved photoemission experiments

Abstract

We report the evolution of the k-space electronic structure of lightly doped bulk Ca2RuO4 with uniaxial strain. Using ultrathin plate-like crystals, we achieve strain levels up to -4.1\%, sufficient to suppress the Mott phase and access the previously unexplored metallic state at low temperature. Angle-resolved photoemission experiments performed while tuning the uniaxial strain reveal that metallicity emerges from a marked redistribution of charge within the Ru t2g shell, accompanied by a sudden collapse of the spectral weight in the lower Hubbard band and the emergence of a well defined Fermi surface which is devoid of pseudogaps. Our results highlight the profound roles of lattice energetics and of the multiorbital nature of Ca2RuO4 in this archetypal Mott transition and open new perspectives for spectroscopic measurements.