# Relation between the weak itinerant magnetism in $A_2$Ni$_7$ compounds   ($A$ = Y, La) and their stacked crystal structures

**Authors:** Jean-Claude Crivello, Val\'erie Paul-Boncour

arXiv: 1903.11423 · 2020-01-08

## TL;DR

This study uses electronic band structure calculations to explore how the stacking of crystal layers influences the weak itinerant magnetic properties of $A_2$Ni$_7$ compounds with $A$ = Y, La, revealing the relationship between structure and magnetic behavior.

## Contribution

It provides a detailed first-principles analysis linking the polymorphic crystal structures of $A_2$Ni$_7$ compounds to their magnetic properties, including ferromagnetic and antiferromagnetic states.

## Key findings

- Both compounds show a sharp peak at the Fermi level indicating magnetic instability.
- $2H$-La$_2$Ni$_7$ is an antiferromagnet, while $3R$-Y$_2$Ni$_7$ is a ferromagnet.
- Ni magnetic moments vary with their positions in the structure.

## Abstract

The weak itinerant magnetic properties of $A_2$Ni$_7$ compounds with $A$ = {Y, La} have been investigated using electronic band structure calculations in the relation with their polymorphic crystal structures. These compounds crystallizes in two structures resulting from the stacking of two and three blocks of [$A_2$Ni$_4$ + 2 $A$Ni$_5$] units for hexagonal $2H$-La$_2$Ni$_7$ (Ce$_2$Ni$_7$ type) and rhombohedral $3R$-Y$_2$Ni$_7$ (Gd$_2$Co$_7$ type) respectively. Experimentally, $2H$-La$_2$Ni$_7$ is a weak itinerant antiferromagnet whereas $3R$-Y$_2$Ni$_7$ is a weak itinerant ferromagnet. From the present first principles calculation within non-spin polarized state, both compounds present an electronic density of state with a sharp and narrow peak centered at the Fermi level corresponding to flat bands from $3d$-Ni. This induces a magnetic instability and both compounds are more stable in a ferromagnetic (FM) order compared to a paramagnetic state ($\Delta E \simeq$ -35 meV/f.u.). The magnetic moment of each of the five Ni sites varies with their positions relative to the [$A_2$Ni$_4$] and [$A$Ni$_5$] units: they are minimum in the [$A_2$Ni$_4$] unit and maximum at the interface between two [$A$Ni$_5$] units. For $2H$-La$_2$Ni$_7$, an antiferromagnetic (AFM) structure has been proposed and found with an energy comparable to that of the FM state. This AFM structure is described by two FM unit blocks of opposite Ni spin sign separated by a non-magnetic layer at z = 0 and $\frac12$. The Ni ($2a$) atoms belonging to this intermediate layer are located in the [La$_2$Ni$_4$] unit and are at a center of symmetry of the hexagonal cell ($P6_3/mmc$) where the resultant molecular field is cancelled. Further non-collinear spin calculations have been performed to determine the Ni moment orientations which are found preferentially parallel to the $c$ axis for both FM and AFM structures.

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Source: https://tomesphere.com/paper/1903.11423