Theory of Room Temperature Ferromagnet V(TCNE)_x (1.5 < x < 2): Role of Hidden Flat Bands

TL;DR

This paper proposes a new crystal structure for V(TCNE)_x, explains room temperature ferromagnetism through localized electron interactions and flat bands, and analyzes the effects of off-stoichiometry and localization.

Contribution

It introduces a novel crystal structure for V(TCNE)_2 and links ferromagnetism to flat bands and localized electron interactions, advancing understanding of molecular ferromagnets.

Findings

Proposed a new crystal structure for V(TCNE)_2.

Identified flat bands as a source of ferromagnetism.

Explained off-stoichiometric ferromagnetism via Anderson localization.

Abstract

Theoretical studies on the possible origin of room temperature ferromagnetism (ferromagnetic once crystallized) in the molecular transition metal complex, V(TCNE)_x (1.5<x<2) have been carried out. For this family, there have been no definite understanding of crystal structure so far because of sample quality, though the effective valence of V is known to be close to +2. Proposing a new crystal structure for the stoichiometric case of x=2, where the valence of each TCNE molecule is -1 and resistivity shows insulating behavior, exchange interaction among d-electrons on adjacent V atoms has been estimated based on the cluster with 3 vanadium atoms and one TCNE molecule. It turns out that Hund's coupling among d orbitals within the same V atoms and antiferromagnetic coupling between d oribitals and LUMO of TCNE (bridging V atoms) due to hybridization result in overall ferromagnetism (to be precise, ferrimagnetism). This view based on localized electrons is supplemented by the band picture, which indicates the existence of a flat band expected to lead to ferromagnetism as well consistent with the localized view. The off-stoichiometric cases (x<2), which still show ferromagnetism but semiconducting transport properties, have been analyzed as due to Anderson localization.