Magnetic clusters in the paramagnetic phase of a high-temperature ferromagnetic metal-organic framework

TL;DR

This study reveals the presence of magnetic clusters in the paramagnetic phase of a high-temperature ferromagnetic metal-organic framework, highlighting complex magnetic dynamics and potential for exploring correlated electron phenomena.

Contribution

It uncovers mesoscopic magnetic clusters and their dynamics in a high-temperature ferromagnetic MOF, providing insights into magnetic behavior above the ordering temperature.

Findings

Development of mesoscopic magnetic clusters in the paramagnetic regime

Observation of slow magnetic dynamics in the MHz range

Similarity to phase segregation in colossal magnetoresistance materials

Abstract

Owing to their exceptional chemical and electronic tunability, metal-organic frameworks can be designed to develop magnetic ground states making a range of applications feasible, from magnetic gas separation to the implementation of lightweight, rare-earth free permanent magnets. However, the typically weak exchange interactions mediated by the diamagnetic organic ligands result in ordering temperatures confined to the cryogenic limit. The itinerant magnetic ground state realized in the chromium-based framework Cr(tri)$_{2}$(CF$_{3}$SO$_{3}$)$_{0.33}$ (Htri, $1H$-$1$,$2$,$3$-triazole) is a remarkable exception to this trend, showing a robust ferromagnetic behavior almost at ambient conditions. Here, we use dc SQUID magnetometry, nuclear magnetic resonance, and ferromagnetic resonance to study the magnetic state realized in this material. We highlight several thermally-activated relaxation mechanisms for the nuclear magnetization due to the tendency of electrons towards localization at low temperatures as well as the rotational dynamics of the charge-balancing triflate ions confined within the pores. Most interestingly, we report the development within the paramagnetic regime of mesoscopic magnetic correlated clusters whose slow dynamics in the MHz range are tracked by the nuclear moments, in agreement with the highly unconventional nature of the magnetic transition detected by dc SQUID magnetometry. We discuss the similarity between the clustered phase in the paramagnetic phase and the magnetoelectronic phase segregation leading to colossal magnetoresistance in manganites and cobaltites. These results demonstrate that high-temperature magnetic metal-organic frameworks can serve as a versatile platform for exploring correlated electron phenomena in low-density, chemically tunable materials.