Isotope tuning of the superconducting dome of strontium titanate

TL;DR

This study investigates how isotope substitution in strontium titanate affects its superconducting transition temperature, revealing that heavier isotopes enhance superconductivity and suggesting a link to ferroelectric fluctuations.

Contribution

It demonstrates that isotope tuning significantly increases Tc in doped SrTiO3, providing new insights into the role of ferroelectric fluctuations in superconductivity.

Findings

Tc increases with higher ^18O concentration.

Maximum Tc occurs at lower carrier densities in ^18O substituted samples.

Superconductivity enhancement supports ferroelectric fluctuation-mediated pairing.

Abstract

Doped strontium titanate SrTiO$_3$ (STO) is one of the most dilute superconductors known today. The fact that superconductivity occurs at very low carrier concentrations is one of the two reasons that the pairing mechanism is not yet understood, the other is the role played by the proximity to a ferroelectric instability. In undoped STO, ferroelectric order can in fact be stabilized by substituting $^{16}$O with its heavier isotope $^{18}$O. Here we explore the superconducting properties of doped and isotope-substituted SrTi$(^{18}$O$_{y}^{16}$O$_{1-y})_{3-\delta}$ for $0\le y \le 0.81$ and carrier concentrations between $6\times 10^{17}$ and $2\times 10^{20}$ cm$^{-3}$ ($\delta<0.02$). We show that the superconducting $T_c$ increases when the $^{18}$O concentration is increased. For carrier concentrations around $5\times 10^{19}$~cm$^{-3}$ this $T_c$ increase amounts to almost a factor $3$, with $T_c$ as high as 580~mK for $y=0.74$. When approaching SrTi$^{18}$O$_3$ the maximum $T_c$ occurs at a much smaller carrier densities than for pure SrTi$^{16}$O$_3$. Our observations agree qualitatively with a scenario where superconducting pairing is mediated by fluctuations of the ferroelectric soft mode.