# Field-induced quantum magnetism in the verdazyl-based charge-transfer   salt $[$$o$-MePy-V-($p$-Br)$_2]$FeCl$_4$

**Authors:** Y. Iwasaki, T. Kida, M. Hagiwara, T. Kawakami, Y. Kono, S. Kittaka, T., Sakakibara, Y. Hosokoshi, and H. Yamaguchi

arXiv: 1812.08334 · 2018-12-21

## TL;DR

This study synthesizes and characterizes a verdazyl-based charge-transfer salt exhibiting complex magnetic behaviors, including a gapped singlet state, antiferromagnetic order, and an unconventional 5/6 magnetization plateau under high magnetic fields.

## Contribution

The paper reports the synthesis and detailed magnetic analysis of a new verdazyl-based salt, revealing unique field-induced quantum magnetic phenomena and the interplay of different spin interactions.

## Key findings

- Identification of a honeycomb lattice of $S_{V}=1/2$ spins with inequivalent sites.
- Observation of a 5/6 magnetization plateau at high magnetic fields.
- Explanation of magnetic behaviors using mean-field and dimer models.

## Abstract

We successfully synthesized a verdazyl-based charge-transfer salt $[$$o$-MePy-V-($p$-Br)$_2]$FeCl$_4$, which has an $S_{\rm{V}}$=1/2 on the radical $o$-MePy-V-($p$-Br)$_2$ and an $S_{\rm{Fe}}$=5/2 on the FeCl$_4$ anion. $Ab$ $initio$ molecular orbital calculations indicate the formation of an $S_{\rm{V}}$=1/2 honeycomb lattice composed of three types of exchange interaction with two types of inequivalent site. Further, the $S_{\rm{V}}$=1/2 at one site is sandwiched by $S_{\rm{Fe}}$=5/2 spins through antiferromagnetic (AF) interactions. The magnetic properties indicate that the dominant AF interactions between the $S_{\rm{V}}$ = 1/2 spins form a gapped singlet state, and the remaining $S_{\rm{Fe}}$ = 5/2 spins cause an AF order. The magnetization curve exhibits a linear increase up to approximately 7 T, and an unconventional 5/6 magnetization plateau appears between 7 T and 40 T. We discuss the differences between the effective interactions associated with the magnetic properties of the present compound and ($o$-MePy-V)FeCl$_4$. We explain the low-field linear magnetization curve through a mean-field approximation of an $S_{\rm{Fe}}$ = 5/2 spin model. At higher field regions, the 5/6 magnetization plateau and subsequent nonlinear increase are reproduced by the $S_{\rm{V}}$ = 1/2 AF dimer, in which a particular internal field is applied to one of the spin sites. The ESR resonance signals in the low-temperature and low-field regime are explained by conventional two-sublattice AF resonance modes with easy-axis anisotropy. These results demonstrate that exchange interactions between $S_{\rm{V}}$ = 1/2 and $S_{\rm{Fe}}$ = 5/2 spins in $[$$o$-MePy-V-($p$-Br)$_2]$FeCl$_4$ realize unconventional magnetic properties with low-field classical behavior and field-induced quantum behavior.

## Full text

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## Figures

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## References

35 references — full list in the complete paper: https://tomesphere.com/paper/1812.08334/full.md

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Source: https://tomesphere.com/paper/1812.08334