Abstract
We report two effects that lead to a significant reduction of the switching field distribution in exchange spring media. The first effect relies on a subtle mechanism of the interplay between exchange coupling between soft and hard layers and anisotropy that allows significant reduction of the switching field distribution in exchange spring media. This effect reduces the switching field distribution by about 30% compared to single-phase media. A second effect is that due to the improved thermal stability of exchange spring media over single-phase media, the jitter due to thermal fluctuation is significantly smaller for exchange spring media than for single-phase media. The influence of this overall improved switching field distribution on the transition jitter in granular recording and the bit error rate in bit-patterned magnetic recording is discussed. The transition jitter in granular recording for a distribution of Khard values of 3% in the hard layer, taking into account thermal fluctuations during recording, is estimated to be a = 0.78 nm, which is similar to the best reported calculated jitter in optimized heat-assisted recording media.
Highlights
We report two effects that lead to a significant reduction of the switching field distribution in exchange spring media
We believe the reason can be found in an improved switching field distribution in exchange spring media, which was predicted by micromagnetic simulations[9]
We have shown that bit error rate (BER) in BPM can be drastically improved by an exchange spring media design
Summary
We report two effects that lead to a significant reduction of the switching field distribution in exchange spring media. The first effect relies on a subtle mechanism of the interplay between exchange coupling between soft and hard layers and anisotropy that allows significant reduction of the switching field distribution in exchange spring media. A second effect is that due to the improved thermal stability of exchange spring media over single-phase media, the jitter due to thermal fluctuation is significantly smaller for exchange spring media than for single-phase media The influence of this overall improved switching field distribution on the transition jitter in granular recording and the bit error rate in bitpatterned magnetic recording is discussed. Exchange spring media lead to an improved signal-to-noise ratio This can obviously not attributed to the main original goal of a small grain size. The improved switching field distribution was reported by various groups[10,11]
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