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Pb(Fe1/2Nb1/2)O3陶瓷中电热效应和磁热效应的共存

The coexistence of electrocaloric and magnetocaloric effects in Pb(Fe1/2Nb1/2)O3 ceramics
课程网址: http://videolectures.net/ipssc2017_prah_ceramics/  
主讲教师: Uroš Prah
开课单位: 约瑟夫·斯特凡研究所
开课时间: 2017-05-23
课程语种: 英语
中文简介:
固态制冷技术是替代低能效、对生态有害的传统蒸汽压缩制冷系统的一种很有前途的替代方法。目前冷却研究中的大多数活动都是研究一种热效应——电热效应(EC)、磁热效应(MC)或机械热效应——即材料的熵在外部刺激(电、磁或机械(应力)的作用下发生变化.1在大块陶瓷材料中,目前的热效应不足以用于商业用途。如何克服这个问题的一个想法是制备一种多热量材料,其中两种或两种以上的单热量效应共存于一种材料中,在这种材料中,两种刺激的应用都可以增强总的多热量效应。此外,不同的热量模式可应用于不同的温度区域,从而扩大冷却装置的工作温度范围。五年前,理论上提出了MC和EC效应共存的观点2,随后是实验构象。3,4制备高效的多色材料非常具有挑战性,对它们的研究尚未完成。在这项工作中,我们通过实验证明了Pb(Fe1/2Nb1/2)O3(PFN)同时具有MC和EC效应,因此是一种多色材料。 为了制备PFN,在高能行星磨机中以300 rpm机械力化学活化均匀的化学计量粉末混合物30 h,并在研磨磨机中以800 rpm研磨4 h。粉末压坯在1273K的氧气气氛中等静压烧结2h。该方法制备的PFN陶瓷理论密度为96%,显微结构均匀,平均晶粒尺寸为2.3μm。使用HP 4284A精密LCR计测量了室温和10kHz下的介电常数和介电损耗,分别为3580和0.038。对于间接EC测量,使用Aixacct TF分析仪2000测量了极化与电场滞后回线。在室温下,在80 kV/cm条件下,EC温度变化为0.81 K。在80 kV/cm和373 K下获得了1.29 K的最大EC温度变化。使用超导量子干涉装置测量了不同磁场下的磁化强度与温度的关系。在50koe和2k时,MC的最大温度变化为0.16k。
课程简介: Solid-state refrigeration technology represents a promising alternative for the replacement of low energy efficient and ecologically harmful conventional vapor-compression refrigeration systems. Most current activity in cooling research is looking at one of the caloric effects – electrocaloric (EC), magnetocaloric (MC) or mechanocaloric – where the material’s entropy changes under the application of external stimuli – electric, magnetic or mechanical (stress).1 In bulk ceramic materials the caloric effect is currently not large enough for commercial use. One idea how to overcome this problem is to prepare a multicaloric material where two or more single caloric effects coexist in one material in which the application of both stimuli can enhance the total, multicaloric effect. Even more, different caloric modes can be applied in different temperature regions extending the operating temperature range of the cooling device. The coexistence of the MC and EC effects had been theoretically proposed five years ago2 followed by experimental conformations.3,4 It is very challenging to prepare efficient multicaloric materials and the search for them is not finished yet. In this work we experimentally prove that the Pb(Fe1/2Nb1/2)O3 (PFN) exhibits both MC and EC effects and is therefore the multicaloric material. For the preparation of the PFN the homogenized, stoichiometric powder mixture was mechanochemically activated in a high-energy planetary mill for 30 h at 300 rpm and milled in an attrition mill for 4 h at 800 rpm. The powder compacts were isostatically pressed and sintered in an oxygen atmosphere at 1273 K for 2 h. This method yielded PFN ceramics with a theoretical density of 96 % and uniform microstructure with average grain size of 2.3 μm. The dielectric permittivity and dielectric losses at room temperature and 10 kHz were measured with a HP 4284A precision LCR Meter and were 3580 and 0.038, respectively. For the indirect EC measurements, the polarization vs. electric field hysteresis loops were measured by an Aixacct TF analyser 2000. At room temperature the EC temperature change was 0.81 K at 80 kV/cm. The maximum EC temperature change of 1.29 K was obtained at 80 kV/cm and 373 K. The magnetization vs. temperature at different magnetic fields was measured using a Superconducting Quantum Interference Device. The maximum MC temperature change of 0.16 K was obtained at 50 kOe and 2 K.
关 键 词: 固态制冷技术; 电热效应; 磁热效应
课程来源: 视频讲座网
数据采集: 2021-11-11:zkj
最后编审: 2021-11-11:zkj
阅读次数: 38

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