We propose a new disk structure for conventional TbFeCo disks, which is suitable for blue
laser light sources, i.e., an additional thin metal layer adjacent to the TbFeCo layer. The metal
layer effectively improved a thermal characteristic of the medium, which resulted in a high
carrier level even in a relatively high readout power. Using the improved medium, high-density
recording was demonstrated in a 407 nm laser and 0.60 numerical aperture (NA) lens
system. Despite the decay of the Kerr effect and photocurrent compared to those in an MD
DATA2 red system, the new medium achieved an acceptable jitter level at a density of only
about 11% lower than that expected from the MTF scaling. This effect
was also found to be effective for a red laser with an NA 0.85 lens.
We studied the performance of the center-aperture-detection type of magnetically induced super-resolution (CAD-MSR) disk using a blue laser diode and an objective lens with a numerical aperture (NA) of 0.6. We confirmed the practicability of I I GbiiJin2 recording density by the evaluation of the system margins. The recording density we confirmed is equivalent to 15 GB user capacity on a I 20-mm-sized disk. We can expect higher recording density by the reduction of the crosstalk.Keywords: magnetooptical disk, magnetically induced super resolution disk, blue laser diode, bit error rate, recording power margin, readout power margin, disk tilt margin,
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