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金属学报  2015, Vol. 51 Issue (7): 799-806    DOI: 10.11900/0412.1961.2015.00084
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强磁场下不同晶粒尺寸Fe薄膜生长模式演变及其对磁性能的影响*
杜娇娇,李国建(),王强,马永会,王慧敏,李萌萌
GROWTH MODE EVOLUTION AND SUBSEQUENT MAGNETIC PROPERTIES OF Fe FILMS WITH DIFFERENT GRAIN SIZES UNDER A HIGH MAGNETIC FIELD
Jiaojiao DU,Guojian LI(),Qiang WANG,Yonghui MA,Huimin WANG,Mengmeng LI
Key Laboratory of Electromagnetic Processing of Materials (Ministry of Education), Northeastern University, Shenyang 110819
引用本文:

杜娇娇,李国建,王强,马永会,王慧敏,李萌萌. 强磁场下不同晶粒尺寸Fe薄膜生长模式演变及其对磁性能的影响*[J]. 金属学报, 2015, 51(7): 799-806.
Jiaojiao DU, Guojian LI, Qiang WANG, Yonghui MA, Huimin WANG, Mengmeng LI. GROWTH MODE EVOLUTION AND SUBSEQUENT MAGNETIC PROPERTIES OF Fe FILMS WITH DIFFERENT GRAIN SIZES UNDER A HIGH MAGNETIC FIELD[J]. Acta Metall Sin, 2015, 51(7): 799-806.

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摘要: 

采用强磁场下物理气相沉积的方法, 通过提高蒸发源温度获得晶粒尺寸逐渐降低的纳米晶Fe薄膜, 研究了强磁场对不同晶粒尺寸Fe薄膜生长和磁性能的影响. 结果表明, 当蒸发源温度为1440 ℃时, Fe薄膜的晶粒细小, 强磁场使薄膜从层状生长变成了柱状生长, 有效降低了薄膜缺陷. 当蒸发源温度为1400和1350 ℃时, Fe薄膜的晶粒较粗大, 强磁场不能改变其柱状生长方式, 但是却提高了柱的宽度. 强磁场提高了Fe薄膜的平均晶粒尺寸以及颗粒(由晶粒构成)尺寸、降低了薄膜表面粗糙度. 随着晶粒尺寸的降低, 强磁场提高Fe薄膜矫顽力、饱和磁化强度和剩磁比的能力增强.

关键词 强磁场Fe薄膜纳米晶柱状生长磁性能    
Abstract

In order to increase the magnetic properties and realize the essential applications in magnetic recording and spintronics devices, it is significant to control the growth mode and grain size of Fe films. In this work, the effects of a high magnetic field (HMF) on the growth and magnetic properties of Fe thin films with different grain sizes by using physics vapor deposition were explored. The decreased grain sizes are obtained by increasing the evaporation source temperatures. It is found that when the evaporation source temperature is 1440 ℃, the grains of film are fine. The growth mode is changed from layered to columnar by HMF. And HMF effectively reduces the defects of Fe film. When the evaporation source temperature is 1400 and 1350 ℃, the grains of films are large. HMF does not change the columnar growth mode of films. However, the width of columns is improved by a HMF. Additionally, HMF increases the average particle (composed of the grains) and grain size of Fe films with different grain sizes. And the surface roughness of all the films is remarkably reduced by a HMF. With the decrease of grain sizes, the ability of HMF on increasing the coercivity, saturation magnetization and squareness ratio of the Fe films is enhanced.

Key wordshigh magnetic field    Fe film    nanocrystalline    columnar growth    magnetic properties
    
基金资助:*国家自然科学基金项目51101034和51425401, 中央高校基本科研业务费项目N130509002和N140902001, 以及辽宁省教育厅科学技术研究一般项目L2014091资助
图1  不同条件下制备Fe薄膜的XRD谱
图2  无磁场下Fe薄膜的生长速率以及不同条件下制备的Fe薄膜的晶粒尺寸
图3  不同条件下制备的Fe薄膜的截面TEM像
图4  不同条件下制备的Fe薄膜的SEM像
图5  不同条件Fe薄膜的AFM像以及线粗糙度分析
图6  不同条件Fe薄膜的室温M-H曲线
图7  不同条件下制备的Fe薄膜当外场平行膜面时的饱和磁化强度Ms, 矫顽力Hc, 剩磁比和应变
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