Recording performance and magnetization switching of CoTb/CoCrPt composite perpendicular media

Recording performance and magnetization switching of CoTb/CoCrPt composite perpendicular media

Magnetic properties, recording performance, and thermal stability of CoTb amorphous/CoCrPt granular composite media are discussed. Thermal stability at low recording density of the composite media with CoCrPtB improves significantly as CoTb thickness increases, in accord with the increase of loop sq...

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Veröffentlicht in:Journal of applied physics 2002-05, Vol.91 (10), p.8058-8060
Hauptverfasser: Uwazumi, H., Shimatsu, T., Sakai, Y., Enomoto, K., Takenoiri, S., Watanabe, S., Muraoka, H., Nakamura, Y.
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container_end_page 8060
container_issue 10
container_start_page 8058
container_title Journal of applied physics
container_volume 91
creator Uwazumi, H.
Shimatsu, T.
Sakai, Y.
Enomoto, K.
Takenoiri, S.
Watanabe, S.
Muraoka, H.
Nakamura, Y.
description Magnetic properties, recording performance, and thermal stability of CoTb amorphous/CoCrPt granular composite media are discussed. Thermal stability at low recording density of the composite media with CoCrPtB improves significantly as CoTb thickness increases, in accord with the increase of loop squareness, Mr/Ms. The media having CoTb thickness of more than 6 nm show almost no signal decay. Moreover, the signal-to-medium-noise ratio, SNR, improves with increasing CoTb thickness up to 6 nm. CoTb(6 nm)/CoCrPtB(20 nm) medium shows the best SNR performance under the present experimental conditions with no thermal decay. Media noise of the composite media with CoCrPt increases super linearly from ∼300 kfci, which is caused by the percolation of the recorded bits, probably due to the strong exchange coupling in the CoTb layer. The media with CoCrPtB shows less media noise than that with CoCrPt, and the super-linear increase of this media noise starts at ∼400 kfci which is higher than that of the media with CoCrPt. It is thought that the well-segregated grain structure of CoCrPtB layer, having the enhanced and fine distribution of Ms, reduces the magnetic cluster size effectively, resulting in the reduction of the media noise.
doi_str_mv 10.1063/1.1452273
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Thermal stability at low recording density of the composite media with CoCrPtB improves significantly as CoTb thickness increases, in accord with the increase of loop squareness, Mr/Ms. The media having CoTb thickness of more than 6 nm show almost no signal decay. Moreover, the signal-to-medium-noise ratio, SNR, improves with increasing CoTb thickness up to 6 nm. CoTb(6 nm)/CoCrPtB(20 nm) medium shows the best SNR performance under the present experimental conditions with no thermal decay. Media noise of the composite media with CoCrPt increases super linearly from ∼300 kfci, which is caused by the percolation of the recorded bits, probably due to the strong exchange coupling in the CoTb layer. The media with CoCrPtB shows less media noise than that with CoCrPt, and the super-linear increase of this media noise starts at ∼400 kfci which is higher than that of the media with CoCrPt. 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