1) magnetocaloric effect of metal Gd
Gd的磁热效应
2) thermomagnetic
[英][,θə:məumæg'netik] [美][,θɝmomæg'nɛtɪk]
热磁[效应]的
3) magnetocaloric effect
磁热效应
1.
Study on magnetocaloric effect of Mn_5(Ge_(3-x)Sb_x)(x=0,0.1,0.2,3) alloys in low magnetic field;
低磁场条件下Mn5(Ge_(3-x)Sb_x)(x=0、0.1、0.2、3)合金磁热效应研究
2.
Influence of heat treatment on magnetocaloric effect of the Mn_5Ge_(2.8)Sb_(0.2) alloy powder prepared by ball miller;
热处理对Mn_5Ge_(2.8)Sb_(0.2)合金粉末磁热效应的影响
3.
Direct measurement of magnetocaloric effect in Gd_(1-x)Zn_x;
Gd_(1-x)Zn_x系合金磁热效应的直接测量
4) thermomagnetic effect
磁热效应
1.
Effect of Zn~(2+) on structure,magnetic properties and thermomagnetic effect of MnZn ferrites;
Zn~(2+)对MnZn铁氧体结构、磁性能和磁热效应的影响
2.
Being placed under the alternative magnetic field, the samples have the obvious thermomagnetic effect.
结果表明 ,R Zn铁氧体具有低居里温度 ;随锌含量的增加 ,试样的居里温度降低 ,具有典型的铁氧体磁滞回线 ;在交变磁场下 ,有明显的磁热效应 。
3.
In order to study the biocompatibility and thermomagnetic effect of MnZn ferrite nanoparticles prepared by citrate auto-combustion method for cancer treatment,ATP cell viability assay and thermomagnetic measurements were applied and the effect of silica coating on cell cytotoxicity and thermomagnetic effect was discussed.
为了探讨SiO2包裹层对纳米磁性微粒的细胞毒性和磁热效应的影响,采用柠檬酸盐自燃烧法制备用于肿瘤磁热疗的纳米MnZn铁氧体微粒,应用ATP细胞活力测试和磁热量测定等方法,对其生物相容性和磁热效应进行测试。
5) magneto-caloric effect
磁热效应
1.
Effect of high-temperature on shape and magneto-caloric effect of La_(0.65)Ca_(0.18)Sr_(0.17)MnO_3 perovskite;
高温对钙钛矿La_(0.65)Ca_(0.18)Sr_(0.17)MnO_3形貌及磁热效应的影响
2.
The experiment shows that the alkalinity and hydrothermal temperature have a great effect on the mineral composition,which then affects the magneto-caloric effect of La0.
研究发现:水热合成钙钛矿样品时,碱度、水热温度对矿物成分有很大影响,进而影响到产物的磁热效应。
3.
In this paper,magnetomechanic effect,magneto-caloric effect,magnetoresistance effect and magnetic-optical effect of magnetic material and its application are discussed by thermodynamic functions.
本文通过热力学函数半定量地讨论了磁性材料的磁力效应、磁热效应,并定性地介绍了磁电阻效应和磁光效应及其应用。
6) thermomagnetic effect
热磁效应
补充资料:磁热效应
磁热效应 magnetocaloric effect 绝热过程中铁磁体或顺磁体的温度随磁场强度的改变而变化的现象。绝热去磁时要降温,又称磁致冷效应。物质的点阵振动和磁矩取向都对系统的熵有贡献,如先在等温情形下加外磁场,物质被磁化,分子磁矩趋向于一致的排列,对熵的贡献减小,系统放出热量;然后在绝热条件下撤去外磁场,磁矩恢复为无规排列,相应的熵增加,但由于是绝热去磁,系统的总熵不变,磁矩的熵的增加是以点阵振动的熵的减少作代价,这导致物质的冷却。绝热去磁与绝热去极化(见电介质物理学)一样可用来获得低温(见超低温技术)。 |
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