Tunable altermagnetism via inter-chain engineering in parallelassembled atomic chains

TL;DR

This paper extends the concept of altermagnetism to quasi-one-dimensional monolayers assembled from atomic chains, identifying stable structures and demonstrating tunability of magnetic and electronic states through inter-chain manipulation and external fields.

Contribution

It introduces a new class of tunable quasi-one-dimensional altermagnets derived from atomic chain assemblies, with insights into their stability and magnetic properties.

Findings

Identified four promising structural prototypes for altermagnetism.

Confirmed eight thermodynamically stable Q1D monolayers via high-throughput calculations.

Demonstrated tunability of magnetic and electronic states through inter-chain spacing and external electric fields.

Abstract

Altermagnetism has recently drawn considerable attention in three- and twodimensional materials. Here, we extend this concept to quasi-one-dimensional (Q1D) monolayers assembled from single-atomic magnetic chains. Through systematically examining nine types of structures, two stacking orders, and intra-/inter-chain magnetic couplings, we identify four out of thirty promising structural prototypes for hosting altermagnetism, which yields 192 potential monolayer materials. We further confirm eight thermodynamically stable Q1D monolayers via high-throughput calculations. Using symmetry analysis and first-principles calculations, we find that the existence of altermagnetism is determined by the type of inter-chain magnetic coupling and predict three intrinsic altermagnets,\(CrBr_3\),\(VBr_3\),\(MnBr_3\),due to their ferromagnetic inter-chain couplings and five extrinsic ones,\(CrF_3\),\(CrCl_3\),\(CrI_3\),\(FeCl_3\)and \(CoTe_3\), ascribed to their neglectable or antiferromagnetic inter-chain couplings. Moreover, the inter-chain magnetic coupling here is highly tunable by manipulating the inter-chain spacing, leading to experimentally feasible transitions between altermagnetic and nodal-line semiconducting states. In addition, applying external electric fields can further modulate the spin splitting. Our findings establish a highly tunable family of Q1D altermagnets, offering fundamental insights into the intricate relationship between geometry, electronic structure, and magnetism.These discoveries hold significant promises for experimental realization and future spintronic applications.