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In this work, Gd20+2xHo20–xEr20–xCo20Ni10Al10 (x = 0, 5, 10) high-entropy metallic glasses (MGs) with a critical diameter of 2 mm are successfully designed and fabricated by substituting Gd, Ho and Er. The effects of type and content of rare-earth (RE) elements on the microstructure, thermodynamic behaviors, and magnetocaloric effect (MCE) are investigated systematically. The amorphous structures of the ribbons and as-cast rods are confirmed by X-ray diffraction (XRD) with Cu Kα radiation (2θ = 20°–80°). The atomic-scale ordered configurations are examined by using high-resolution transmission electron microscope (HRTEM). Thermal analysis is carried out on differential scanning calorimeter (DSC) with a heating rate of 20 K/min by using ribbons. The magnetic measurements are conducted by using magnetometer in a temperature range of 5–180 K. According to DSC traces, it is suggested that as Ho and Er are replaced by Gd, the thermal stability of MGs slightly decreases, for example, both glass transition temperature (Tg) and initial crystallization temperature (Tx) decrease gradually, meanwhile the liquidus temperature (Tl) increases, which results in a reduction of glass-forming ability criteria such as the reduced glass transition temperatures Trg (Trg = Tg/Tl), γ (γ = Tx/(Tg + Tl)), and γm (γm = (2Tx – Tg)/Tl), thermodynamically. The analyses based on XRD and HRTEM show that the degree of order in MGs decreases with Gd content increasing, which facilitates the glass formation. The magnetocaloric parameters such as Curie temperature (Tc), maximum magnetic entropy change ($ | {\Delta S_{\text{M}}^{{\text{pk}}}} | $) and relative cooling power (RCP) all increase gradually with the addition of Gd. The Gd40Ho10Er10CoNiAl exhibits the best refrigeration performance in all studied systems, where the peak value of $ |{\Delta S}_{{\mathrm{M}}}| $ is 8.31 J/(kg·K) and RCP is 740.82 J/kg. The results indicate that MCEs of MGs including RCP, Tc and $ | {\Delta S_{\text{M}}^{{\text{pk}}}} | $, mainly depend on the de Gennes factor rather than the effective magnetic moment, while thermodynamic properties are more affected by the f-d hybridization effect. As the number of 4f electrons increases, the thermal stability increases with the degree f-d orbital hybridization increasing. In summary, the RE-based MG with high thermal stability and adjustable Tc can be achieved by the RE substitution via adjusting the number of 4f electrons.
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Keywords:
- rare-earth based high-entropy metallic glasses /
- thermodynamic properties /
- magnetocaloric effect /
- glass forming ability
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图 1 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金条带(a)和铸棒(b)的XRD图谱
Figure 1. XRD patterns of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10) ribbons (a) and rods (b).
图 2 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金条带HRTEM图(a)—(c)及选区二维自相关处理图(d)—(f), 插图为选区电子衍射图
Figure 2. (a)−(c) HRTEM image of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10) ribbons and (d)−(f) 2D auto-correlation processing image of selected area. The inset shows the selected area electron diffraction pattern.
图 3 (a) Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10) 非晶合金条带DSC图; (b) Tg和Tx与4f电子数的关系图
Figure 3. (a) DSC traces of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10) ribbons; (b) Tg and Tx as a function of 4f electron number.
图 4 (a) Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金200 Oe外场场冷和零场冷磁化强度与温度关系图; (b) 200 Oe外场下的$ {1 {/ } {\chi \left( T \right)}} $随温度变化曲线; (c)场冷曲线求导图; (d) Tc与G因子的关系
Figure 4. (a) Temperature dependence of ZFC and FC magnetization curves (M-T) of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10) under 200 Oe; (b) $ {1 {/ } {\chi \left( T \right)}} $ curves at H = 200 Oe; (c) dM/dT-T curves; (d) Tc as a function of G factor.
图 5 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金不同温度下磁化强度与外场关系图(a)—(c)和Arrott图(d)—(f); 不同外场下的磁熵变与温度关系图(g)—(i)和$|\Delta S_{\text{M}}/ | {\Delta S_{\text{M}}^{{\text{pk}}}} |\text{-}\theta$图(j)—(l)
Figure 5. Isothermal magnetization curves (M-H ) (a)–(c) and Arrott plots (d)–(f); magnetic entropy changes as a function of temperature (|ΔSM|-T ) (g)–(i) and $|\Delta S_{\text{M}}/ | {\Delta S_{\text{M}}^{{\text{pk}}}} |\text{-}\theta$ curves (j)–(l) for Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10).
图 6 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金5 T外场下磁熵变与温度关系图, 插图为3种合金相对制冷量值
Figure 6. Magnetic entropy changes as a function of temperature (|ΔSM|-T) of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10) under an applied field of 5 T. The inset is RCP value.
图 7 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金(a)峰值磁熵变和(b)相对制冷能力与外场关系图, 实线为指数函数拟合曲线
Figure 7. (a) Maximum magnetic entropy changes and (b) relative cooling power as a function of applied field ($ | {\Delta S_{\text{M}}^{{\text{pk}}}} | $/RCP-H ) for Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10). The solid lines are the exponential function fitting curves.
图 8 (a) Tc, (b) $ | {\Delta S_{\text{M}}^{{\text{pk}}}} | $和(c) RCP与G因子的关系
Figure 8. (a) Tc, (b) $ | {\Delta S_{\text{M}}^{{\text{pk}}}} | $, and (c) RCP as a function of G factor.
图 9 (a) Tg, (b) Tx和(c) ΔTx与4f层电子数的关系
Figure 9. (a) Tg, (b) Tx, and (c) ΔTx as a function of 4f electron number.
表 1 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金热力学参数(R为气体常数)
Table 1. Thermodynamic parameters and GFA criteria of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10).
Compositions ΔSconf 4f electron number Tg/K Tx/K Tl/K ΔTx/K Trg γ γm x = 0 1.748R 9.33 560.6 616.3 973.0 55.7 0.576 0.402 0.691 x = 5 1.713R 8.75 554.8 613.9 989.6 59.1 0.561 0.398 0.680 x = 10 1.609R 8.17 551.3 605.3 985.6 54.0 0.559 0.394 0.669 
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表 2 Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10)非晶合金的磁热参数
Table 2. Magnetocaloric parameters of Gd20+2xHo20–xEr20–xCoNiAl (x = 0, 5, 10).
x ΔSconf G-factor Tc/K θ/K μeff/μB(实验) μeff/μB(理论) $ | {\Delta S_{\text{M}}^{{\text{pk}}}} | $/(J·kg–1·K–1) δTFWHM/K RCP/(J·kg–1) n N 0 1.748R 7.60 65 17.968 7.18 7.75 8.21 73.99 607.20 0.80 1.00 5 1.713R 9.64 67 77.788 6.68 7.45 8.28 80.43 665.67 0.78 1.00 10 1.609R 11.68 81 92.191 6.61 7.14 8.31 89.17 740.82 0.76 1.01
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[1] Gschneidner K A, Pecharsky V, Tsokol A 2005 Rep. Prog. Phys. 68 1479
Google Scholar
[2] Uporov S, Ryltsev R, Bykov V, Uporova N, Estemirova S K, Chtchelkatchev N 2021 J. Alloys Compd. 854 157170
Google Scholar
[3] Warburg E 1881 Ann. Der. Phys. 249 141
Google Scholar
[4] Debye P 1926 Ann. Der. Phys. 386 1154
Google Scholar
[5] Giauque W F 1927 J. Am. Chem. Soc. 49 1864
Google Scholar
[6] Pecharsky V K, Gschneidner Jr K A 1997 Phys. Rev. Lett. 78 4494
Google Scholar
[7] Pecharsky V K, Gschneidner Jr K A 1997 Appl. Phys. Lett. 70 3299
Google Scholar
[8] Jia Y S, Zhao X Y, Liu X L, Li L W 2020 J. Alloys Compd. 813 152177
Google Scholar
[9] Zhang Y K, Zhu J, Li S, Zhang B, Wang Y M, Wang J, Ren Z M 2022 J. Alloys Compd. 895 162633
Google Scholar
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Google Scholar
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Google Scholar
[12] Lim X 2016 Nature 533 306
Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
[34] Zheng Z G, Qiu Z G, Zeng D C 2019 Mater. Res. Express 6 096109
Google Scholar
[35] Law J Y, Ramanujan R V, Franco V 2010 J. Alloys Compd. 508 14
Google Scholar
[36] 糜晓磊, 胡亮, 武博文, 龙强, 魏炳波 2024 73 097102
Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
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2024年24期217101补充材料.pdf
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