Pressure-Driven Transitions in La2CoTiO6: Antiferromagnetic Insulator to Nonmagnetic Metal via Antiferromagnetic Metal in a Double Perovskite Oxide
Abstract
In double perovskite oxides (A2BB6), magnetism often arises from diluted magnetic lattices, created by combining a perovskite structure with localized 3d magnetic elements (B) alongside another perovskite lattice containing nearly nonmagnetic delocalized 4d/5d elements (B). Alternatively, the magnetic lattice can consist entirely of 3d elements, with one being completely nonmagnetic with d0 state. La2CoTiO6 (LCTO), a representative double perovskite oxide, contains Ti in a nonmagnetic state with a d0 electron configuration due to its 4+ oxidation state. Experimental evidence shows that LCTO possesses a monoclinic structure (space group P21/n) and behaves as an antiferromagnet with a N\'eel temperature of 14.6 K. Through first-principle electronic structure calculations, we uncover that adjusting external hydrostatic pressure induces a sequence of phase transitions: from antiferromagnetic insulator (AFM-I) to antiferromagnetic metal (AFM-M), and ultimately to itinerant nonmagnetic metal (NM-M). The transition from AFM-I to AFM-M at 42 GPa pressure coincides with a shift in spin states, moving from a high-spin (HS) state to a low-spin (LS) state, while Co retains a d7 configuration. Distortion within the monoclinic structure under pressure plays a pivotal role in the spin-state transition. At the AFM-I to AFM-M transition, we observe a sharp decrease in the ratio of the octahedral volumes occupied by Co and Ti. Such change in ratio is linked to variations in octahedral volumes, akin to a breathing mode distortion. We explore the impact of the breathing mode distortion by examining a highly symmetric theoretical structure (space-group I4/mmm), achieved by optimizing the structure with all Co-O-Ti angles set to 180.
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