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MA: Fachverband Magnetismus
MA 39: SrTiO3: A Versatile Material from Bulk Quantum Paraelectric to 2D Superconductor II (joint session TT/KFM/MA/O)
MA 39.2: Vortrag
Donnerstag, 21. März 2024, 15:15–15:30, H 0104
Dilute superconductivity in the vicinity of a ferroelectric quantum critical point coupled via the "vector coupling": The case of SrTiO3 — •Sudip Kumar Saha1,2, Avraham Klein1, Jonathan Ruhman2, and Maria Navarro Gastiasoro3 — 1Ariel University, Israel — 2Bar-Ilan University, Israel — 3Donostia International Physics Center, Spain
Lightly doped SrTiO3 (STO) is one of the most studied examples of quantum ferroelectric metal (QFEMs), where superconductivity coexists with ferroelectric order. Pristine STO is paraelectric naturally close to a ferroelectric quantum critical point (QCP). Strain or chemical substitution (for example, doping with Ba/Ca instead of Sr) drives STO through the QCP to the ferroelectric phase, which manifests itself in the softening of the transverse optical (TO) phonon mode. Doped samples are superconducting, where the Tc vs. density dome extends to very low density. To date, there is no consensus on the mechanism leading to superconductivity at such low density. Edge et al. have proposed that the ferroelectric QCP and dilute superconductivity are related [Phys. Rev. Lett. 115, 247002 (2015)]. In this work we explore the possible origin of low-density superconductivity from coupling linearly to the TO mode via a "vector coupling". We solve the critical-Eliashberg theory numerically, including fermionic and bosonic self-energy corrections, which allows us access all the way to the QCP. Notably, all our calculations are justified within standard approaches. We find the existence of a superconducting dome with magnitude and dependence on the distance from the QCP that resembles experiments.
Keywords: Quantum critical point; Soft transverse optical phonon mode; Ferroelectricity; Superconductivity; Eliashberg theory