Tuning the giant Magnetocaloric Effect and refrigerant capacity in Gd1–xYxCrO3 (0.0 ≤ x ≤ 0.9) perovskites nanoparticles

IF 1.4 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY AIMS Materials Science Pub Date : 2022-01-01 DOI:10.3934/matersci.2022018
I. Al-Omari, Muna Al-Mamari, D. Sellmyer
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Abstract

Different compounds of rare-earth orthochromites Gd1–xYxCrO3 (where x is 0.0–0.9) powder nanoparticles, were synthesized by the auto-combustion method followed by annealing at 700 ℃. All the compounds showed single-phase and crystallized into a distorted orthorhombic structure with the space group (Pbnm). The average particle size for all the samples were in the range 53–110 nm. The detailed and systematic magnetic measurements and analysis showed that all the samples up to x = 0.9 have large magnetization and large values of the change in the magnetic entropy. The magnitude of the change in the magnetic entropy (at 4.5 K and for all the values of the change in the applied magnetic field between 1 and 9 T) is found to increase with increasing x reaching a maximum value at x = 0.3 then it decreases as we increase the yttrium concentration. The nanoparticle compounds with low yttrium concentrations showed a giant change in the magnetic entropy and a giant relative cooling power. Based on the slopes of Arrott plots curves the order parameter of the magnetic transition has been estimated and found to be second order. The giant change in the magnetic entropy and the relative cooling power were tuned in the rages (-45.6 to -8.7 J/kg·K at a change in the applied magnetic field of 9 T; and 136–746 J/kg), around the helium liquefaction temperature. The magnitude of the change in the magnetic entropy is significantly larger for large range of temperatures, up to the nitrogen liquefaction temperature. The giant change in the magnetic entropy and the giant relative cooling power at low temperatures (in the range about 4 to 20 K.) make these samples candidate materials for the low temperature magnetic refrigerant applications, based on the magnetocaloric effect.
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调节Gd1-xYxCrO3(0.0≤x≤0.9)钙钛矿纳米颗粒的巨磁热效应和制冷剂容量
采用自燃烧法合成了不同种类的稀土正铬铁矿Gd1-xYxCrO3 (x为0 ~ 0.9)粉末纳米颗粒,并在700℃下进行退火。所有化合物均为单相,结晶成具有空间基团(Pbnm)的畸变正交结构。所有样品的平均粒径在53 ~ 110 nm之间。详细而系统的磁测量和分析表明,x = 0.9以下的样品都具有较大的磁化强度和较大的磁熵变化值。磁熵的变化幅度(在4.5 K时,外加磁场在1到9 T之间的所有变化值)随着x的增加而增加,在x = 0.3时达到最大值,然后随着钇浓度的增加而减小。低钇纳米颗粒化合物表现出巨大的磁熵变化和巨大的相对冷却能力。根据Arrott曲线的斜率估计了磁跃迁的阶参量,发现其阶参量为二阶。当外加磁场为9 T时,磁熵和相对冷却功率的巨大变化范围为-45.6 ~ -8.7 J/kg·K;和136 ~ 746 J/kg),在氦液化温度附近。在较大的温度范围内,直至氮气液化温度,磁熵的变化幅度明显更大。磁熵的巨大变化和低温下的巨大相对冷却功率(在4到20 k的范围内)使这些样品成为基于磁热效应的低温磁性制冷剂应用的候选材料。
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来源期刊
AIMS Materials Science
AIMS Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
3.60
自引率
0.00%
发文量
33
审稿时长
4 weeks
期刊介绍: AIMS Materials Science welcomes, but not limited to, the papers from the following topics: · Biological materials · Ceramics · Composite materials · Magnetic materials · Medical implant materials · New properties of materials · Nanoscience and nanotechnology · Polymers · Thin films.
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