Title :
Demonstration of thermomechanical recording at 641 Gbit/in2
Author :
Pozidis, H. ; Häberle, W. ; Wiesmann, D. ; Drechsler, U. ; Despont, M. ; Albrecht, T.R. ; Eleftheriou, E.
Author_Institution :
IBM Zurich Res. Lab., Ruschlikon, Switzerland
fDate :
7/1/2004 12:00:00 AM
Abstract :
Ultrahigh storage areal densities can be achieved by using thermomechanical local-probe techniques to write, read back, and erase data in the form of nanometer-scale indentations in thin polymer films. This paper presents single-probe experimental results in which large data sets were recorded at 641 Gbit/in2 and read back with raw bit-error rates better than 10-4. (d,k) modulation coding is used to mitigate the effect of partial erasing, occurring when subsequent indentations are spaced too closely together, and to increase the effective areal density. The physical indentation profile, the sensitivity of the probe in readback mode, and noise sources that affect data detection are also discussed. Quantitative measurements of the partial erasing effect in both the on-track and cross-track directions are reported.
Keywords :
atomic force microscopy; data recording; error statistics; micromechanical devices; modulation coding; storage media; thermomechanical treatment; areal density experiments; bit-error rates; cross-track direction; data detection; data read back; data set recording; modulation coding; nanometer-scale indentation; noise sources; on-track direction; partial erasing; physical indentation profile; probe sensitivity; probe storage; storage areal density; thermomechanical local-probe techniques; thermomechanical recording; thin polymer films; Amorphous magnetic materials; FETs; Flash memory; Image storage; Magnetic recording; Perpendicular magnetic recording; Polymer films; Probes; Reproducibility of results; Thermomechanical processes; Areal density experiments; probe storage; thermomechanical recording;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2004.830470
