Unconventional Superconductivity Induced by Quantum Critical Fluctuations in Hydrate Cobaltate Na$_{x}$(H$_3$O)$_{z}$CoO$_{x}\cdot$ $y$H$_{2}$O -- Relationship between Magnetic Fluctuations and the Superconductivity Revealed by a Co Nuclear Quadrupole Resonance --

TL;DR

This study investigates how quantum critical magnetic fluctuations influence unconventional superconductivity in hydrate cobaltates, revealing a phase diagram where superconductivity emerges near a magnetic quantum critical point.

Contribution

It demonstrates that the NQR frequency zz can serve as a tuning parameter to control the ground state, linking magnetic fluctuations to superconductivity in hydrate cobaltates.

Findings

Samples with zz > 4.2 MHz show magnetic order.

Samples with lower zz exhibit superconductivity.

Superconductivity peaks near the quantum critical point where magnetic order vanishes.

Abstract

Co nuclear-quadrupole-resonance (NQR) measurements were performed on various bilayered hydrate cobaltate Na_x(H_3O)_zCoO_2\cdot yH_2O with different values of the superconducting and magnetic-ordering temperatures, T_c and T_M, respectively. From measurements of the temperature and sample dependence of the NQR frequency, it was revealed that the NQR frequency is changed by the change of the electric field gradient (EFG) along the c axis \nu_{zz} rather than the asymmetry of EFG within the ab-plane. In addition, it is considered that the change of \nu_{zz} is gaverned mainly by the trigonal distortion of the CoO_2 block layers along the c axis, from the relationships between \nu_{zz} and the various physical parameters. We found the tendency that samples with \nu_{zz} larger than 4.2 MHz show magnetic ordering, whereas samples with lower \nu_{zz} show superconductivity. We measured the nuclear spin-lattice relaxation rate 1/T_1 in these samples, and found that magnetic fluctuations depend on samples. The higher-\nu_{zz} sample has stronger magnetic fluctuations at T_c. From the relationship between \nu_{zz} and T_c or T_M, we suggest that the NQR frequency can be regarded as a tuning parameter to determine the ground state of the system, and develop the phase diagram using \nu_{zz}. This phase diagram shows that the highest-T_c sample is located at the point where T_M is considered to be zero, which suggests that the superconductivity is induced by quantum critical fluctuations. We strongly advocate that the hydrate cobaltate superconductor presents an example of the magnetic-fluctuation-mediated superconductivity argued in the heavy-fermion compounds. The coexistence of superconductivity and magnetism observed in the sample with the highest \nu_{zz} is also discussed on the basis of the results of our experiments.