Supporting data from: Fermi-liquid transport beyond the upper critical field in superconducting La2PrNi2O7 thin films
Data files
Mar 20, 2026 version files 440.35 KB
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LPNO_Hallresistivity_sample1.xlsx
72.87 KB
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LPNO_magnetoresistivity_sample1.xlsx
143.43 KB
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LPNO_zerofieldresistivity.xlsx
222.05 KB
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README.md
1.99 KB
Abstract
Unconventional superconductivity typically emerges out of a strongly correlated normal state, manifesting as a highly renormalised Fermi liquid or a strange metal with T-linear resistivity. In Ruddlesden-Popper bilayer nickelates, superconductivity with a critical temperature Tc exceeding 80 and 40 K has been respectively realised in pressurised bulk crystals and epitaxially strained thin films. These advancements call for the characterisation of fundamental normal-state and superconducting parameters in these new materials platforms of high-Tc superconductivity. Here we report detailed magnetotransport experiments on superconducting La2PrNi2O7 (LPNO) thin films under pulsed magnetic fields up to 64 T and access the normal-state behaviour over a wide temperature range between 1.5 and 300 K. We find that the normal state of thin-film LPNO exhibits the hallmarks of Fermi-liquid transport, including T2 temperature dependence of resistivity and Hall angle, and H2 magnetoresistance obeying Kohler scaling. Using the empirical Kadowaki-Woods ratio, we estimate a quasiparticle effective mass m*/me ≃ 10, thereby revealing the highly renormalised Fermi liquid state therein. Our results demonstrate that thin-film LPNO follows the same Tc/TF scaling observed across a myriad of strongly correlated superconductors and establish key normal-state characteristics of strained bilayer superconducting nickelates.
Dataset DOI: 10.5061/dryad.m0cfxpphs
Description of the data and file structure
Source figure data for research article "Fermi0liquid transport beyond the upper critical field in superconducting La2PrNi2O7 thin films"
This dataset contains three Excel files with the raw data used to create the main figures in the manuscript. Resistivity values are in micro-Ohm centimeter (uohm.cm) with the number in the first-row showings the temperature values in kelvin. The contents of each data file are explained below.
Files and variables
File: LPNO_zerofieldresistivity.xlsx
Description: Zero-field resistivity of two LPNO samples
In-plane resistivity (rho) as a function of Temperature (T) in zero applied magnetic field for two samples: sample 1 (tab #1) and sample 2 (tab #2).
Variables
- x: temperature in unit of kelvin (K)
- y: resistivity in unit of micro-ohm centimeter (uohm.cm)
File: LPNO_Hallresistivity_sample1.xlsx
Description: Hall resistivity as a function of magnetic field at constant temperatures
Hall resistivity as a function of magnetic field at constant temperatures as specified in the first row.
Variables
- x: magnetic field in unit of tesla (T)
- y: resistivity in unit of micro-ohm centimeter (uohm.cm)
File: LPNO_magnetoresistivity_sample1.xlsx
Description: In-plane resistivity as a function of magnetic field at constant temperatures
In-plane resistivity (rho) as a function of Magnetic field up to 52.5 T, at constant temperature values specified in the first row (in unit of K).
Variables
- x: magnetic field in unit of tesla (T)
- y: resistivity in unit of micro-ohm centimeter (uohm.cm)
Access information
Other publicly accessible locations of the data:
- n/a
Data was derived from the following sources:
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