# Multielemental single-atom-thick A layers in nanolaminated V2(Sn, A)C   (A=Fe, Co, Ni, Mn) for tailoring magnetic properties

**Authors:** Youbing Li, Jun Lu, Mian Li, Keke Chang, Xianhu Zha, Yiming Zhang, Ke, Chen, Per O. A. Persson, Lars Hultman, Per Eklund, Shiyu Du, Zhifang Chai,, Zhengren Huang, Qing Huang

arXiv: 1908.03709 · 2020-03-25

## TL;DR

This study introduces a novel nanolaminated material with multielement single-atom-thick layers, enabling atomic-level control of magnetic properties through alloying in the A layers, expanding the design space for advanced magnetic materials.

## Contribution

It demonstrates the synthesis of multielement alloyed nanolaminates with tailored magnetic properties, a largely unexplored area in atomic-layer engineering.

## Key findings

- Distinct ferromagnetic behavior observed in alloyed layers.
- Magnetic properties can be tuned by composition.
- Structural design expands chemical and property space.

## Abstract

Tailoring of individual single-atom-thick layers in nanolaminated materials offers atomic-level control over material properties. Nonetheless, multielement alloying in individual atomic layers in nanolaminates is largely unexplored. Here, we report a series of inherently nanolaminated V2(A'xSn1-x)C (A'=Fe, Co, Ni and Mn, and combinations thereof, with x=1/3) synthesized by an alloy-guided reaction. The simultaneous occupancy of the four magnetic elements and Sn, the individual single-atom-thick A layers in the compound constitute high-entropy-alloy analogues, two-dimensional in the sense that the alloying exclusively occurs in the A layers. V2(A'xSn1-x)C exhibit distinct ferromagnetic behavior that can be compositionally tailored from the multielement A-layer alloying. This two-dimensional alloying provides a structural-design route with expanded chemical space for discovering materials and exploit properties.

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Source: https://tomesphere.com/paper/1908.03709