Spin-3/2 nuclear magnetic resonance: Exact solutions for aligned systems and implications for probing Fe-based superconductors

TL;DR

This paper derives exact analytical solutions for spin-3/2 NMR spectra in aligned systems, providing tools to analyze magnetic and structural properties of Fe-based superconductors with implications for experimental and theoretical studies.

Contribution

It introduces exact closed-form expressions for spin-3/2 NMR spectra in aligned systems, enhancing interpretation and analysis of complex spectra in superconducting materials.

Findings

Derived compact analytical expressions for eigenstates and transition frequencies.

Applied the theory to zero-field NMR spectra of Fe-based superconductors.

Demonstrated improved interpretation of NMR data compared to traditional methods.

Abstract

The nuclear magnetic resonance (NMR) spectrum of spin-3/2 nuclei in a static magnetic field aligned with one of the electric field gradient (EFG) principal axes is developed analytically, based on fictitious spin-1/2 formalism. Compact closed-form expressions for the eigenstates and transitions frequencies, as well as the expectation value of the magnetic moment after resonant excitation, are derived. Emphasis is placed on defining and interpreting the associated Rabi frequencies, as a function of excitation direction and ellipticity. It is found transitions inherently fall into two subsets, depending on their sensitivity to excitation direction, with the Rabi frequency of one subset directly depending on the asymmetry of the EFG. A natural application is the study of Fe-based superconductors, whose antiferromagnetic ordering at low temperatures leads to a strong intrinsic magnetic field aligned with the EFG principal axes. Zero external-field NMR spectra, from powder samples of two such Fe-based superconductors, BaFe$_2$As$_2$ and CaFe$_2$As$_2$, are analyzed and exemplify the simplicity in extracting the internal magnetic field, the quadrupole coupling constant, and the EFG asymmetry parameter, which are important for studying magnetic ordering, structural properties, phase transitions, and NMR dynamics. Results compare favorably to conventional high-field NMR experiments done with the rotation of single crystals. Overall, the physical insights, afforded by the exact and concise expressions, will lead to ready interpretation of spin-3/2 spectra as well as precipitate new experimental directions.