Inhomogeneous magnetic ordered state and evolution of magnetic fluctuations in Sr(Co1-xNix)2P2 revealed by 31P NMR
Abstract
SrCo2P2 with a tetragonal structure is known to be a Stoner-enhanced Pauli paramagnetic metal being nearly ferromagnetic. Recently Schmidt et al. [Phys. Rev. B 108, 174415 (2023)] reported that a ferromagnetic ordered state is actually induced by a small Ni substitution for Co of x = 0.02 in Sr(Co1-xNix)2P2 where antiferromagnetic ordered phase also appears by further Ni-substitution with x = 0.06-0.35. Here, using nuclear magnetic resonance (NMR) measurements on 31P nuclei, we have investigated how the magnetic properties change by the Ni substitution in Sr(Co1-xNix)2P2 from a microscopic point of view, especially focusing on the evolution of magnetic fluctuations with the Ni substitution and the characterization of the magnetically ordered states. The temperature dependences of 31P spin-lattice relaxation rate divided by temperature (1/T1T) and Knight shift (K) for SrCo2P2 are reasonably explained by a model where a double-peak structure for the density of states near the Fermi energy is assumed. Based on a Korringa ratio analysis using the T1 and K data, ferromagnetic spin fluctuations are found to dominate in the ferromagnetic Sr(Co1-xNix)2P2 as well as the antiferromagnets where no clear antiferromagnetic fluctuations are observed. We also found the distribution of the ordered Co moments in the magnetically ordered states from the analysis of the 31P NMR spectra exhibiting a characteristic rectangular-like shape.
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