Recent developments and perspective of zero thermal expansion magnetic materials

Qi Shen; Niels van Dijk; Lingwei Li; Ekkes Brück

doi:10.1016/bs.hmm.2025.09.001

Recent developments and perspective of zero thermal expansion magnetic materials

Qi Shen^*, Niels van Dijk, Lingwei Li, Ekkes Brück

^*Corresponding author for this work

RST/Fundamental Aspects of Materials and Energy

Research output: Chapter in Book/Conference proceedings/Edited volume › Chapter › Scientific › peer-review

Abstract

Zero thermal expansion (ZTE) materials, which maintain a constant length despite temperature variations, are highly desirable for advanced industrial applications. This chapter highlights recent progress in exploring ZTE behaviour in Fe-based Laves phases, La-Fe-Si(Al)-based alloys, rare-earth-based alloys, hexagonal MM′X alloys and Mn-based antiperovskite with a giant magnetocaloric effect. The abnormal lattice expansion observed in giant magnetocaloric materials, driven by magnetic interactions, provides a natural foundation for the design of ZTE materials. Furthermore, key properties such as the mechanical strength, thermal and electrical conductivity, and plasticity are discussed. This chapter offers new insights into the design and discovery of novel ZTE magnetic materials, paving the way for advancements in functional materials.

Original language	English
Title of host publication	Handbook of Magnetic Materials
Editors	Ekkes Brück
Publisher	Elsevier
Chapter	1
Pages	1-43
Number of pages	43
Volume	34
ISBN (Electronic)	9780128210239
ISBN (Print)	9780443428418
DOIs	https://doi.org/10.1016/bs.hmm.2025.09.001
Publication status	Published - 2025

Publication series

Name	Handbook of Magnetic Materials
Volume	34
ISSN (Print)	1567-2719

Keywords

Magnetocaloric effect
Magnetoelastic transition
Magnetostructural transition
Negative thermal expansion
Zero thermal expansion

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10.1016/bs.hmm.2025.09.001

Cite this

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title = "Recent developments and perspective of zero thermal expansion magnetic materials",

abstract = "Zero thermal expansion (ZTE) materials, which maintain a constant length despite temperature variations, are highly desirable for advanced industrial applications. This chapter highlights recent progress in exploring ZTE behaviour in Fe-based Laves phases, La-Fe-Si(Al)-based alloys, rare-earth-based alloys, hexagonal MM′X alloys and Mn-based antiperovskite with a giant magnetocaloric effect. The abnormal lattice expansion observed in giant magnetocaloric materials, driven by magnetic interactions, provides a natural foundation for the design of ZTE materials. Furthermore, key properties such as the mechanical strength, thermal and electrical conductivity, and plasticity are discussed. This chapter offers new insights into the design and discovery of novel ZTE magnetic materials, paving the way for advancements in functional materials.",

keywords = "Magnetocaloric effect, Magnetoelastic transition, Magnetostructural transition, Negative thermal expansion, Zero thermal expansion",

author = "Qi Shen and {van Dijk}, Niels and Lingwei Li and Ekkes Br{\"u}ck",

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doi = "10.1016/bs.hmm.2025.09.001",

language = "English",

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volume = "34",

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T1 - Recent developments and perspective of zero thermal expansion magnetic materials

AU - Shen, Qi

AU - van Dijk, Niels

AU - Li, Lingwei

AU - Brück, Ekkes

PY - 2025

Y1 - 2025

N2 - Zero thermal expansion (ZTE) materials, which maintain a constant length despite temperature variations, are highly desirable for advanced industrial applications. This chapter highlights recent progress in exploring ZTE behaviour in Fe-based Laves phases, La-Fe-Si(Al)-based alloys, rare-earth-based alloys, hexagonal MM′X alloys and Mn-based antiperovskite with a giant magnetocaloric effect. The abnormal lattice expansion observed in giant magnetocaloric materials, driven by magnetic interactions, provides a natural foundation for the design of ZTE materials. Furthermore, key properties such as the mechanical strength, thermal and electrical conductivity, and plasticity are discussed. This chapter offers new insights into the design and discovery of novel ZTE magnetic materials, paving the way for advancements in functional materials.

AB - Zero thermal expansion (ZTE) materials, which maintain a constant length despite temperature variations, are highly desirable for advanced industrial applications. This chapter highlights recent progress in exploring ZTE behaviour in Fe-based Laves phases, La-Fe-Si(Al)-based alloys, rare-earth-based alloys, hexagonal MM′X alloys and Mn-based antiperovskite with a giant magnetocaloric effect. The abnormal lattice expansion observed in giant magnetocaloric materials, driven by magnetic interactions, provides a natural foundation for the design of ZTE materials. Furthermore, key properties such as the mechanical strength, thermal and electrical conductivity, and plasticity are discussed. This chapter offers new insights into the design and discovery of novel ZTE magnetic materials, paving the way for advancements in functional materials.

KW - Magnetocaloric effect

KW - Magnetoelastic transition

KW - Magnetostructural transition

KW - Negative thermal expansion

KW - Zero thermal expansion

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M3 - Chapter

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Recent developments and perspective of zero thermal expansion magnetic materials

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