Phase Diagram of Nickelate Superconductors Calculated by Dynamical Vertex Approximation

Abstract: We review the electronic structure of nickelate superconductors with and without effects of electronic correlations. As a minimal model, we identify the one-band Hubbard model for the Ni 3dx2−y2 orbital plus a pocket around the A-momentum. The latter, however, merely acts as a decoupled electron reservoir. This reservoir makes a careful translation from nominal Sr-doping to the doping of the one-band Hubbard model mandatory. Our dynamical mean-field theory calculations, in part already supported by the experim… Show more

“…The theoretical (DΓA) result (yellow circles) is roughly consistent with the experimental value of 15K at 20%-doping (red diamond) [5]. Furthermore, the T c dome structure around 20%-doping is also compatible with subsequent experiments [103,104,105] (please see the review article [106] for details of nickelate calculations). We note that the ignored d-wave pairing fluctuation effect and the interlayer coupling will somewhat decrease T c while we expect these are secondary (minor) effects as mentioned in Sec.…”

Strongly correlated superconductivity with long-range spatial fluctuations

“…The theoretical (DΓA) result (yellow circles) is roughly consistent with the experimental value of 15K at 20%-doping (red diamond) [5]. Furthermore, the T c dome structure around 20%-doping is also compatible with subsequent experiments [103,104,105] (please see the review article [106] for details of nickelate calculations). We note that the ignored d-wave pairing fluctuation effect and the interlayer coupling will somewhat decrease T c while we expect these are secondary (minor) effects as mentioned in Sec.…”

Strongly correlated superconductivity with long-range spatial fluctuations

“…Such models has already been successfully applied in the description of the superconducting phase in NdNiO 2 [28][29][30] and the non-Curie-Weiss behavior of the magnetic susceptibility in LaNiO 2 [18]. The material realistic hopping parameters, resulting from a Wannier-and tight-binding projection are t = 395meV, t′ = − 0.25t = − 95 meV, and t″ = 0.12t = 47 meV as well as the local Hubbard interaction U = 8t = 3.16 eV from a cRPA calculation [28].…”

Magnetic Properties and Pseudogap Formation in Infinite-Layer Nickelates: Insights From the Single-Band Hubbard Model

“…For undoped LaNiO 2 , the GGA-PBEsol relaxations predict its in-plane lattice constant as 3.890 Å whichis close to that of the STO substrate: 3.905 Å. The computations for La 1−x Ca x NiO 2 and LaCoO 2 , LaCuO 2 , SrCoO 2 and SrNiO 2 are performed without spin-polarization and a DFT+U treatment [79], as the inclusion of Coulomb U and spin-polarization only slightly decreases the E b by ∼5% for LaNiO 2 [66] . For NdNiO 2 , an inevitably computational issue are the localized Nd-4 f orbitals.…”

“…Besides avoiding topotactic H, compressive strain is also predicted as an effectively way to enhance T c . Previous dynamical vertex approximation calculations [27,66] reveal the key to enhance T c in nickelates is to enhance the bandwidth W and to reduce the ratio of Coulomb interaction U to W. Based on this prediction, we have proposed [27,66] three experimental ways to enhance T c in nickelates: (1) in-plane compressive strain, which can indeed be achieved by using other substrates having a smaller lattice than STO, such as LSAT (3.868 Å), LaAlO 3 (3.80 Å) or SrLaAlO 4 (3.75 Å). The smaller in-plane lattice shrinks the distance between Ni atoms thus increases their orbital overlap, leading to a larger W and a smaller U/W.…”

Fingerprints of Topotactic Hydrogen in Nickelate Superconductors