Tuning the Magnetocaloric Properties of the La(Fe,Si)13 Compounds by Chemical Substitution and Light Element Insertion

Paul‐Boncour, V.; Bessaïs, L.

doi:10.3390/magnetochemistry7010013

Cited by 19 publications

(14 citation statements)

References 90 publications

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“…The La(Fe 1– x ,Si x ) 13 -derived compounds are very well known for their giant magnetocaloric effect and NTE behavior. ,,,,,,− Their crystal structure is cubic with Fm-3c space group, and they display a ferromagnetic-to-paramagnetic (FM-PM) isostructural transition, corresponding to a low-temperature high-magnetization (ordered) state that evolves into a high-temperature low-magnetization (disordered) state as the temperature is increased across their T C . Along these transitions, the crystal structure is retained, but the unit cell volume contracts by 3000–30,000 ppm typically over a <50 K temperature interval. ,,,− To act as compensators, NTE materials should have a more gradual change of volume over a larger temperature window, akin to the typical changes on standard PTE materials.…”

Section: Introductionmentioning

confidence: 99%

Tailoring Negative Thermal Expansion via Tunable Induced Strain in La–Fe–Si-Based Multifunctional Material

Fleming

Gonçalves

Davarpanah

et al. 2022

ACS Appl. Mater. Interfaces

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Zero thermal expansion (ZTE) composites are typically designed by combining positive thermal expansion (PTE) with negative thermal expansion (NTE) materials acting as compensators and have many diverse applications, including in high-precision instrumentation and biomedical devices. La(Fe1–x ,Si x )13-based compounds display several remarkable properties, such as giant magnetocaloric effect and very large NTE at room temperature. Both are linked via strong magnetovolume coupling, which leads to sharp magnetic and volume changes occurring simultaneously across first-order phase transitions; the abrupt nature of these changes makes them unsuitable as thermal expansion compensators. To make these materials more useful practically, the mechanisms controlling the temperature over which this transition occurs and the magnitude of contraction need to be controlled. In this work, ball-milling was used to decrease particles and crystallite sizes and increase the strain in LaFe11.9Mn0.27Si1.29H x alloys. Such size and strain tuning effectively broadened the temperature over which this transition occurs. The material’s NTE operational temperature window was expanded, and its peak was suppressed by up to 85%. This work demonstrates that induced strain is the key mechanism controlling these materials’ phase transitions. This allows the optimization of their thermal expansion toward room-temperature ZTE applications.

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Section: Introductionmentioning

confidence: 99%

Tailoring Negative Thermal Expansion via Tunable Induced Strain in La–Fe–Si-Based Multifunctional Material

Fleming

Gonçalves

Davarpanah

et al. 2022

ACS Appl. Mater. Interfaces

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“…66 There are various techniques for the preparation of LaFe 13−x Si x compounds such as arc-melting, induction melting, ball milling, melt spinning, hot pressing, spark plasma sintering, etc. 67 The mixing of rare earth materials to achieve the nearroom-temperature Curie transition temperature is the main challenge during the preparation of LaFe 13−x Si x . 64 Ball milling is one technique that may be used to decrease the particle size of bulk materials; 68 however, it is a batch process that makes use of surfactants, which can inhibit magnetic response.…”

Section: Gd-based Materialsmentioning

confidence: 99%

“…To reduce the diffusion route, they primarily rely on a reduction in particle size and close contact between the various phases formed during casting. 67 From the literature, it is evident that most of the methods used for preparation of magnetocaloric La(Fe,Si) 13 are physical-or vacuum-based deposition methods which are not cost-effective. 3 The commercialization of magnetic refrigeration or scaling up to an industrial level needs low-cost methods to be employed.…”

Section: Fe Lamentioning

confidence: 99%

A Short Review on the Evolution of Magnetocaloric La(Fe,Si)₁₃ and Its Fabrication through Melt Spinning

Vinod,

Arvindha Babu,

Wuppulluri

2024

ACS Omega

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Energy-efficient refrigeration technology needs to advance ineluctably due to rising energy consumption and diminishing fossil fuel and primitive hydrocarbon reserves. Further, the existing gas compression method releases huge amount of chlorofluorocarbons (CFCs) that deplete the ozone layer. This is a global concern, which demands an immediate remedial technology. As a potential solution to the problem of sustainability and a means of meeting the everincreasing demand for energy, environmentally friendly and socially responsible renewable energy sources could serve as an ideal replacement for traditional refrigeration technology. Solid-state refrigeration using magnetocaloric materials is one prominent technique that can be adopted for clean and economical refrigeration or cooling requirements. In this review, we briefly introduce the present understanding on magnetocaloric LaFe 13−x Si x alloys with a specific emphasis on their application in magnetic refrigeration. This paper deals with the advantages and disadvantages of different synthesis methods for producing LaFe 13−x Si x and enhancing its magnetocaloric effects. Annealing time, yield, composition, and relative cooling power are examined as prospective industrial implementation factors for the La(Fe,Si) 13 synthesis process. The initial sections have been devoted to an overview of the magnetocaloric effect and its different types and history. Further, the article reviews the evolution of a new preparation method called melt spinning, other synthesizing methods, and some developments around the world for the prototypes of La(Fe,Si)-based magnetic refrigeration methods. According to the findings in the scholarly literature, the synthesis process of melt spinning has the potential to be commercialized because of its capacity to create huge quantities of La(Fe,Si) 13 with a high purity in a very short amount of time.

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“…Meanwhile, the proposed compound system has a shortcoming of the splitting phenomenon, which is correlated with the diffusion of hydrogens [24,25,[32][33][34]. To overcome this drawback in long-term reliability, the alloy design should now admit a co-doping technique of rare-earth elements and Mn to La(Fe,Si) 13 H systems [34][35][36][37]. Although this approach brings about the laborious complexity, degrees of freedom are provided in the alloy design.…”

Section: Introductionmentioning

confidence: 99%

Magnetocaloric properties in (La,R)(Fe,Mn,Si)₁₃H (R = Ce and Pr)—toward a better alloy design that results in a reduction in volume of permanent magnets and the establishment of long-term reliability in cooling systems

Fujita

Imaizumi

2023

J. Phys. Energy

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The magnetocaloric effect (MCE) in La1−z R z (Fe0.89−x Mn x Si0.11)13H y max (R = Ce and Pr) is verified in view of correlation between alloying recipes such as selection of doping elements and fundamental physics that governs MCE. The Ce-doped specimen with z = 0.3 & x = 0.017 exhibits a peaky isothermal entropy change ΔS M profile with a maximum value of 20 J kg−1 K under a field change of 0.8 T at the Curie temperature of 285 K. In contrast, the enlarged field dependence of the Curie temperature and diminished hysteresis results in the adiabatic temperature change ΔT ad of 2.7 K under a field change of 0.8 T at the Curie temperature of 289 K for the Pr-doped specimen.

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Tuning the Magnetocaloric Properties of the La(Fe,Si)13 Compounds by Chemical Substitution and Light Element Insertion

Cited by 19 publications

References 90 publications

Tailoring Negative Thermal Expansion via Tunable Induced Strain in La–Fe–Si-Based Multifunctional Material

Tailoring Negative Thermal Expansion via Tunable Induced Strain in La–Fe–Si-Based Multifunctional Material

A Short Review on the Evolution of Magnetocaloric La(Fe,Si)₁₃ and Its Fabrication through Melt Spinning

Magnetocaloric properties in (La,R)(Fe,Mn,Si)₁₃H (R = Ce and Pr)—toward a better alloy design that results in a reduction in volume of permanent magnets and the establishment of long-term reliability in cooling systems

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Tuning the Magnetocaloric Properties of the La(Fe,Si)13 Compounds by Chemical Substitution and Light Element Insertion

Cited by 19 publications

References 90 publications

Tailoring Negative Thermal Expansion via Tunable Induced Strain in La–Fe–Si-Based Multifunctional Material

Tailoring Negative Thermal Expansion via Tunable Induced Strain in La–Fe–Si-Based Multifunctional Material

A Short Review on the Evolution of Magnetocaloric La(Fe,Si)13 and Its Fabrication through Melt Spinning

Magnetocaloric properties in (La,R)(Fe,Mn,Si)13H (R = Ce and Pr)—toward a better alloy design that results in a reduction in volume of permanent magnets and the establishment of long-term reliability in cooling systems

Contact Info

Product

Resources

About

A Short Review on the Evolution of Magnetocaloric La(Fe,Si)₁₃ and Its Fabrication through Melt Spinning

Magnetocaloric properties in (La,R)(Fe,Mn,Si)₁₃H (R = Ce and Pr)—toward a better alloy design that results in a reduction in volume of permanent magnets and the establishment of long-term reliability in cooling systems