Effect of magnetic field on the superconducting phase in the electron-doped metallic double-chain compound Pr$_{2}$Ba$_{4}$Cu$_{7}$O$_{15-\delta}$

TL;DR

This study investigates how magnetic fields influence the superconducting phase in Pr$_{2}$Ba$_{4}$Cu$_{7}$O$_{15-\delta}$, revealing discrepancies between resistive and magnetic measurements and discussing the role of quasi-one-dimensional CuO double chains.

Contribution

It provides new insights into the magnetic response and superconductivity suppression mechanisms in a metallic double-chain cuprate, combining experimental magnetotransport and magnetization data with theoretical band calculations.

Findings

Resistive critical magnetic field ~21 T at low temperatures.

Magnetization critical field ~0.3 T at 2 K.

Discrepancies suggest disappearance of magnetic shielding effect.

Abstract

We report the magnetotransport and $dc$ magnetic susceptibility of the polycrystalline samples of Pr$_{2}$Ba$_{4}$Cu$_{7}$O$_{15-\delta}$, to examine the effect of magnetic field on the superconducting phase of the metallic CuO double chain. The resistive critical magnetic field is estimated to be about 21 T at low temperatures from the resistive transition data. On the other hand, the corresponding critical field determined from the magnetization measurements gives rise to a very low value of $\sim 0.3$T at 2 K. These discrepancies in the magnetic response between the resistivity and magnetization data are caused by disappearance of the magnetically shielding effect even in relatively lower fields. In spite of the observation of the resistive drop associated with the superconducting transport currents, the suppression of the diamagnetic signal is probably related to the superconductivity of quasi one-dimensional CuO double-chain. The behavior of Seebeck coefficient in the superconducting Pr$_{2}$Ba$_{4}$Cu$_{7}$O$_{15-\delta}$ is discussed on the basis of the double chain model from the density functional band calculation.