Fe 입자를 미세 분산 시킨 AlN 박막의 물리적 성질

한창석; 김장우; Chang Suk Han; Jang Woo Kim

Korean Journal of Materials Research, Vol.21, No.1, 28-33, January, 2011

DOI10.3740/MRSK.2011.21.1.028 Export Citation

Fe 입자를 미세 분산 시킨 AlN 박막의 물리적 성질

Physical Properties of Fe Particles Fine-dispersed in AlN Thin Films

한창석^†, 김장우¹

호서대학교 국방과학기술학과
¹호서대학교 디지털디스플레이공학과

Chang Suk Han^†, and Jang Woo Kim¹

Dept. of Defense Science & Technology, Hoseo University, Korea
¹Dept. of Digital Display Engineering, Hoseo University, 165 Sechul-Ri, Baebang-Myun, Asan City, Chungnam 336-795, Korea

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This paper describes the fabrication of AlN thin films containing iron and iron nitride particles, and the magnetic and electrical properties of such films. Fe-N-Al alloy films were deposited in Ar and N2 mixtures at ambient temperature using Fe/Al composite targets in a two-facing-target DC sputtering system. X-ray diffraction results showed that the Fe-N-Al films were amorphous, and after annealing for 5 h both AlN and bcc-Fe/bct-FeNx phases appeared. Structure changes in the FeNx phases were explained in terms of occupied nitrogen atoms. Electron diffraction and transmission electron microscopy observations revealed that iron and iron nitride particles were randomly dispersed in annealed AlN films. The grain size of magnetic particles ranged from 5 to 20 nm in diameter depending on annealing conditions. The saturation magnetization as a function of the annealing time for the Fe55N20Al25 films when annealed at 573, 773 and 873 K. At these temperatures, the amount of iron/iron nitride particles increased with increasing annealing time. An increase in the saturation magnetization is explained qualitatively in terms of the amount of such magnetic particles in the film. The resistivity increased monotonously with decreasing Fe content, being consistent with randomly dispersed iron/iron nitride particles in the AlN film. The coercive force was evaluated to be larger than 6.4 × 103 Am.1 (80 Oe). This large value is ascribed to a residual stress restrained in the ferromagnetic particles, which is considered to be related to the present preparation process.

Keywords:AlN thin film;magnetic property;electrical resistivity;annealing

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[4] Ohnuma S, Fujimori H, Yano N, Furukawa S, Fujii S, Masumoto T, J. Magn. Magn. Mater., 126, 556 (1993)

[5] Kim KJ, Park JY, Kim KY, Noh TH, Kang IK, J. Kor. Magnetic. Soc., 5(5), 491 (1995)

[6] Brien V, Pigeat P, J. Cryst. Growth, 299(1), 189 (2007)

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[8] Muktepavela F, Manika I, Grigorjeva L, Skvortsova V, Proc. of SPIE, oi:10.1117/12.515693, 5122, 434 (2003)

[9] Parkin SSP, More N, Roche KP, Phys. Rev. Lett., 64(19), 2304 (1990)

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[19] Han CS, Lee J, J. Korean Society for Heat Treatment, 19(6), 320 (2006)

[20] Mamiya H, Nakatani I, J. Magnetics Society of Japan, 25(4), 691 (2001)