Interplay between Ferroelectricity and Superconductivity – IFAS

We have performed electrical, thermal and thermoelectric transport measurements over a wide temperature range. We used Hall microprobes to measure the first critical field and performed Raman spectroscopy measurements.

Ferroelectric and metallicity in Sr1-xCaxTiO3-d
A bound to thermal diffusivity in insulators-
Phonon hydrodynamics-
A thermal Hall effect generated by phonons-
Vortex Nernst signal in superconductors-
T-square resistivity without Umklapp scattering-
Linear and isotropic magnetoresistance of lightly doped strontium titanate
Hybridization of acoustic and optical phonons in strontium titanate

Despite the problems caused by the health crisis, this research has given rise to numerous publications. Others will follow.

24 publications in journals like Annual Reviews of Condensed Matter, Nature Communications, Science Advances,, Physical Review X, Physical Review Letters, Physical Review Materials, Physical Review B, Journal of Physics: Condensed Matter,...

Among doped semiconductors with a superconducting ground state, SrTiO3 is distinguished by the precocity of its superconductivity. With only 10-5 electron per formula unit (f.u.), the system becomes superconducting. When the carrier density exceeds 0.02/f.u., it ceases to be so. This superconducting dome raises two distinct and still unanswered questions: how does superconductivity persist in the dilute limit despite the hierarchy inversion between Fermi and Debye temperatures? Why does it disappear on the overdoped side in spite of the steady increase in the electronic density of states? The insulating parent of this remarkable superconductor is a quantum paraelectric, which becomes a true ferroelectric by replacing strontium with calcium. The two partners have recently discovered that the two orders coexist in Ca-substituted-oxygen-deficient strontium titanate. At first sight, such a coexistence appears surprising. Ferroelectricity is a state of matter in which the solid hosts a macroscopic reversible static electric dipole. Since mobile electrons of a metal are expected to screen such a dipole, only ionic insulators which lack inversion symmetry are expected to qualify as true ferroelectrics. Superconductivity is an electron instability in a metal triggered by an attractive interaction overcoming the Coulomb repulsion among electrons and creating Cooper pairs which condensate macroscopically. These two states of matter have little in common. Their mutual exclusiveness was considered even stronger than the documented animosity between superconductivity and magnetism. In the words of Matthias written in 1967: “…not ferromagnetism but ferroelectricity instead should be the phenomenon most incompatible with superconductivity."
However, we have found that when mobile electrons and electric dipoles are both dilute, they can coexist and the superconducting instability of electrons and ferroelectric alignment of dipoles do not impede each other [2]. This experimental observation raises a host of new questions: How many mobile electrons does it take to screen a dipole? What are the dynamics of the screening process in the dilute limit? How do dipoles inside a Fermi sea communicate with each other? How do Cooper pairs and aligned dipoles interact? How to compare ferroelectric quantum criticality with its magnetic counterpart?
This proposal aims to document the consequences of the proximity between ferroelectric, superconducting and antiferrodistortive orders in SrTiO3 subject to various dopants (niobium, lanthanum, calcium, barium, oxygen vacancies…) as well as in its sister compounds EuTiO3 and KTaO3. The two partners possess complementary expertise. The German partner has been active in exploring the complex conductance in a broad range of frequency and has strong expertise in single-crystal growth of rare-earth titanates and thermodynamic studies of quantum phase transitions. The French partner has been studying electric, thermoelectric and thermal transport at zero frequency in extreme conditions of temperature and magnetic field.