Worm, P., Si, L., Kitatani, M., Arita, R., Tomczak, J. M., & Held, K. (2022). Correlations tune the electronic structure of pentalayer nickelates into the superconducting regime. Physical Review Materials, 6(9), L091801-1-L091801-6. https://doi.org/10.1103/PhysRevMaterials.6.L091801
strongly correlated electron systems; spin fluctuations; superconductivity
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Abstract:
Motivated by the recent discovery of superconductivity in the pentalayer nickelate Nd6Ni5O12 [G. A. Pan, Nat. Mater. 21, 160 (2022)10.1038/s41563-021-01142-9], we calculate its electronic structure and superconducting critical temperature. We find that electronic correlations are essential for pushing Nd6Ni5O12 into the superconducting doping range as they shift the electron pockets above the Fermi energy. As a consequence, Nd6Ni5O12 can be described with a single dx2-y2 orbital per Ni. We predict the pentalayer to be overdoped; further improvements in Tc can be expected for a few additional layers. Instead, for the bilayer nickelate Nd3Ni2O6 we find correlations to drive the system into a three-orbital regime also involving the Ni dxz,yz states. We suggest, however, that single-orbital physics with optimal doping can be restored by substituting 60% of the trivalent Nd or La by tetravalent Zr.
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Research facilities:
Vienna Scientific Cluster
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Project title:
Adaptive Magnus-Integratoren für Quantensysteme: P 30819-N32 (Fonds zur Förderung der wissenschaftlichen Forschung (FWF)) elektronische Korrelationen auf dem 3-Teilchen-Niveau: P 32044-N32 (Fonds zur Förderung der wissenschaftlichen Forschung (FWF))
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Research Areas:
Quantum Many-body Systems Physics: 20% Computational Materials Science: 80%