Microalloying effect of Y on magnetocaloric properties of GdTbDyHo rare earth high entropy alloys

Liang Wang; Wenli Song; Zhichao Lu; Suihe Jiang; Xiongjun Liu; Xiaobin Zhang; Hui Wang; Yuan Wu; Dong Ma; Zhaoping Lü

doi:10.1007/s12613-025-3307-3

International Journal of Minerals, Metallurgy, and Materials ›› 2026, Vol. 33 ›› Issue (3) :899 -907. DOI: 10.1007/s12613-025-3307-3

Research Article

research-article

Microalloying effect of Y on magnetocaloric properties of GdTbDyHo rare earth high entropy alloys

Author information +

History +

PDF

Abstract

High-entropy magnetocaloric alloys offer exceptional compositional flexibility and stability for magnetic refrigeration. However, enhancing their magnetic entropy change, working temperature range, and refrigeration capacity remains challenging. In this study, we demonstrate that microalloying GdTbDyHo with only 0.4at% nonmagnetic Y effectively addresses this limitation. Our analysis indicates that Y uniformly dissolves into the hexagonal matrix lattice, disrupting the 4f–4f exchange interactions and inducing a local short-range order. This weakens the antiferromagnetic coupling, accelerates the antiferromagnetic–ferromagnetic transition, and broadens its range. Consequently, the peak magnetic entropy change increases from 8.2 to 8.7 J·kg⁻¹·K⁻¹, the working temperature range expands from 77 to 89 K, and the refrigeration capacity improves by 23%, reaching 774 J·kg⁻¹ (5 T) relative to the Y-free alloy, while the Néel temperature remains constant (∼195 K). This study establishes nonmagnetic microalloying as a cost-effective and scalable strategy for designing high-performance magnetocaloric materials.

Keywords

high-entropy alloys / microalloying / magnetocaloric effect / magnetic entropy change / refrigeration capacity

Cite this article

Download citation ▾

Liang Wang, Wenli Song, Zhichao Lu, Suihe Jiang, Xiongjun Liu, Xiaobin Zhang, Hui Wang, Yuan Wu, Dong Ma, Zhaoping Lü. Microalloying effect of Y on magnetocaloric properties of GdTbDyHo rare earth high entropy alloys. International Journal of Minerals, Metallurgy, and Materials, 2026, 33(3): 899-907 DOI:10.1007/s12613-025-3307-3

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	S. Kumar, R. Muhammad, S. Kim, J. Yi, K. Son, and H. Oh, Exploring magnetocaloric materials for sustainable refrigeration near hydrogen gas liquefaction temperature, Adv. Funct. Mater., 34(2024), No. 39, art. No. 2402513.

[2]	T. Gottschall, K.P. Skokov, M. Fries, et al., Making a cool choice: The materials library of magnetic refrigeration, Adv. Energy Mater., 9(2019), No. 34, art. No. 1901322.

[3]	Warburg E. Magnetische untersuchungen. Ann. Der Phys.. 1881, 2495141.

[4]	Sari O, Balli M. From conventional to magnetic refrigerator technology. Int. J. Refrig.. 2014, 378.

[5]	Pecharsky VK, KAGJr. Magnetocaloric effect and magnetic refrigeration. J. Magn. Magn. Mater.. 1999, 2001–344.

[6]	Tishin AM. Magnetocaloric effect: Current situation and future trends. J. Magn. Magn. Mater.. 2007, 3162351.

[7]	Shen BG, Sun JR, Hu FX, Zhang HW, Cheng ZH. Recent progress in exploring magnetocaloric materials. Adv. Mater.. 2009, 21454545.

[8]	N.A. Zarkevich and V.I. Zverev, Viable materials with a giant magnetocaloric effect, Crystals, 10(2020), No. 9, art. No. 815.

[9]	Tishin AM, Spichkin YI. Recent progress in magnetocaloric effect: Mechanisms and potential applications. Int. J. Refrig.. 2014, 37223.

[10]	Brück E. Developments in magnetocaloric refrigeration. J. Phys. D: Appl. Phys.. 2005, 3823R381.

[11]	Phan MH, Yu SC. Review of the magnetocaloric effect in manganite materials. J. Magn. Magn. Mater.. 2007, 3082325.

[12]	Gómez JR, Garcia RF, Catoira ADM, Gómez MR. Magnetocaloric effect: A review of the thermodynamic cycles in magnetic refrigeration. Renewable Sustainable Energy Rev.. 2013, 1774.

[13]	M. Balli, S. Jandl, P. Fournier, and A.K. Lebouc, Advanced materials for magnetic cooling: Fundamentals and practical aspects, Appl. Phys. Rev., 4(2017), No. 2, art. No. 021305.

[14]	L. Wang, Z.C. Lu, H.J. Guo, et al., Multi-principal rare-earth Gd–Tb–Dy–Ho–Er alloys with high magnetocaloric performance near room temperature, J. Alloy. Compd., 960(2023), art. No. 170901.

[15]	K. Klinar, J.Y. Law, V. Franco, X. Moya, and A. Kitanovski, Perspectives and energy applications of magnetocaloric, pyromagnetic, electrocaloric, and pyroelectric materials, Adv. Energy Mater., 14(2024), No. 39, art. No. 2401739.

[16]	Y. Taguchi, H. Sakai, and D. Choudhury, Magnetocaloric materials with multiple instabilities, Adv. Mater., 29(2017), No. 25, art. No. 1606144.

[17]	W. Chen, J.L. Lin, X. Wang, and L.W. Li, Structural, magnetic, and cryogenic magnetocaloric properties of Gd₁₁O₁₀(SiO₄)(PO₄)₃ phosphosilicate, J. Magn. Magn. Mater., 626(2025), art. No. 173107.

[18]	L.W. Li and M. Yan, Recent progresses in exploring the rare earth based intermetallic compounds for cryogenic magnetic refrigeration, J. Alloy. Compd., 823(2020), art. No. 153810.

[19]	Hu FX, Shen BG, Sun JR, Cheng ZH, Rao GH, Zhang XX. Influence of negative lattice expansion and metamagnetic transition on magnetic entropy change in the compound LaFe_11.4Si_1.6. Appl. Phys. Lett.. 2001, 78233675.

[20]	Krenke T, Duman E, Acet Met al. . Inverse magnetocaloric effect in ferromagnetic Ni–Mn–Sn alloys. Nat. Mater.. 2005, 46450.

[21]	Franco V, Blázquez JS, Ipus JJ, Law JY, Ramírez LMM, Conde A. Magnetocaloric effect: From materials research to refrigeration devices. Prog. Mater. Sci.. 2018, 93112.

[22]	Li TY, Xie ZL, Zhou WJet al. . Study on the hydrogen absorption properties of a YGdTbDyHo rare-earth high-entropy alloy. Int. J. Miner. Metall. Mater.. 2025, 321127.

[23]	Liu QH, Du Q, Zhang XBet al. . Characterization of local chemical ordering and deformation behavior in high entropy alloys by transmission electron microscopy. Int. J. Miner. Metall. Mater.. 2024, 315877.

[24]	Yang X, Chen DZ, Feng L, Qin G, Wu SP, Chen RR. Enhancing the mechanical properties of casting eutectic high-entropy alloys via W addition. Int. J. Miner. Metall. Mater.. 2024, 3161364.

[25]	Wang Y, Wang W, Park JH, Mu WZ. Effect of hafnium and molybdenum addition on inclusion characteristics in Co-based dual-phase high-entropy alloys. Int. J. Miner. Metall. Mater.. 2024, 3171639.

[26]	Malatji N, Popoola API, Lengopeng T, Pityana S. Effect of Nb addition on the microstructural, mechanical and electrochemical characteristics of AlCrFeNiCu high-entropy alloy. Int. J. Miner. Metall. Mater.. 2020, 27101332.

[27]	J.Y. Law, L.M. Moreno-Ramírez, Á. Díaz-García, and V. Franco, Current perspective in magnetocaloric materials research, J. Appl. Phys., 133(2023), No. 4, art. No. 040903.

[28]	A. Kitanovski, Energy applications of magnetocaloric materials, Adv. Energy Mater., 10(2020), No. 10, art. No. 1903741.

[29]	Law JY, Franco V. Review on magnetocaloric high-entropy alloys: Design and analysis methods. J. Mater. Res.. 2023, 38137.

[30]	Perrin A, Laughlin DE, McHenry ME. High entropy alloys: Magnetocaloric effects. Encyclopedia of Materials: Metals and Alloys. 2022, Amsterdam, Elsevier484.

[31]	Yuan Y, Wu Y, Tong Xet al. . Rare-earth high-entropy alloys with giant magnetocaloric effect. Acta Mater.. 2017, 125481.

[32]	W.H. Zhu, L. Ma, M.F. He, et al., Large refrigerant capacity induced by table-like magnetocaloric effect in high-entropy alloys TbDyHoEr, Adv. Eng. Mater., 25(2023), No. 11, art. No. 2201770.

[33]	J.Y. Law and V. Franco, Pushing the limits of magnetocaloric high-entropy alloys, APL Mater., 9(2021), No. 8, art. No. 080702.

[34]	Z.G. Zhang, Q. Luo, L.L. Shao, L. Xue, B. Chen, and B.L. Shen, Tuning magnetocaloric effect of Gd–Co–Al–Si bulk metallic glass via controlling degree of structural order, J. Magn. Magn. Mater., 545(2022), art. No. 168769.

[35]	Yin H, Law JY, Huang YJet al. . Enhancing the magnetocaloric response of high-entropy metallic-glass by microstructural control. Sci. China Mater.. 2022, 6541134.

[36]	L. Wang, Z.C. Lu, Y. Wu, et al., Effect of Sc addition on magnetocaloric properties of GdTbDyHo high-entropy alloys, Adv. Eng. Mater., 26(2024), No. 4, art. No. 2300616.

[37]	Yang X, Zhang Y. Prediction of high-entropy stabilized solid-solution in multi-component alloys. Mater. Chem. Phys.. 2012, 1322–3233.

[38]	Lu SF, Ma L, Rao GHet al. . Magnetocaloric effect of high-entropy rare-earth alloy GdTbHoErY. J. Mater. Sci. Mater. Electron.. 2021, 32810919.

[39]	S.A. Uporov, E.V. Sterkhov, I.A. Balyakin, V.A. Bykov, I.S. Sipatov, and A.A. Rempel, Synthesis and magnetic properties of some monotectic composites containing ultra-dispersed particles of YGdTbDyHo high-entropy alloy, Intermetallics, 165(2024), art. No. 108121.

[40]	Takeuchi A, Inoue A. Classification of bulk metallic glasses by atomic size difference, heat of mixing and period of constituent elements and its application to characterization of the main alloying element. Mater. Trans.. 2005, 46122817.

[41]	J. Lužnik, P. Koželj, S. Vrtnik, et al., Complex magnetism of Ho–Dy–Y–Gd–Tb hexagonal high-entropy alloy, Phys. Rev. B, 92(2015), No. 22, art. No. 224201.

[42]	Carvajal JR. Recent advances in magnetic structure determination by neutron powder diffraction. Physica B: Condens. Matter. 1993, 1921–255.

[43]	S.A. Uporov and E.V. Sterkhov, Magnetocaloric effect in Gd-Sc solid solutions, Solid State Commun., 380(2024), art. No. 115444.

[44]	Banerjee BK. On a generalised approach to first and second order magnetic transitions. Phys. Lett.. 1964, 12116.

[45]	Chaudhary V, Chen X, Ramanujan RV. Iron and manganese based magnetocaloric materials for near room temperature thermal management. Prog. Mater. Sci.. 2019, 10064.

[46]	A.V. Svalov, D.S. Neznakhin, A.V. Arkhipov, et al., Magnetic and magnetocaloric properties of melt-spun ribbons of GdTbDyHoEr high entropy alloy, Appl. Phys. A, 131(2025), No. 3, art. No. 174.

[47]	Zhang YK. Review of the structural, magnetic and magnetocaloric properties in ternary rare earth RE₂T₂X type intermetallic compounds. J. Alloy. Compd.. 2019, 7871173.