Open AccessThe thermodynamic limits of magnetic recording
Author(s) -
Hans Richter,
A. Lyberatos,
U. Nowak,
Richard F. L. Evans,
R.W. Chantrell
Publication year - 2012
Publication title -
journal of applied physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.699
H-Index - 319
eISSN - 1089-7550
pISSN - 0021-8979
DOI - 10.1063/1.3681297
Subject(s) - limit (mathematics) , terabit , thermal , materials science , thermodynamics , linear density , stability (learning theory) , upper and lower bounds , micromagnetics , computer science , magnetic storage , statistical physics , condensed matter physics , magnetization , physics , mathematics , optoelectronics , magnetic field , quantum mechanics , mathematical analysis , wavelength , wavelength division multiplexing , machine learning
Thermal stability of the recorded information is generally thought to set the limit of the maximum possible density in magnetic recording. It is shown that basic thermodynamics always cause the probability of success of the write process to be less than 100%. This leads to a thermally induced error rate, which eventually limits the maximum possible density beyond that given by the traditional thermal stability limit. While the thermally induced error rate is negligible for recording of simple single domain particles, it rapidly increases in the presence of a write assist, in particular if the write assist is accomplished by an increased recording temperature. For the ultimate recording system that combines thermally assisted writing with a recording scheme that uses one grain per bit, the upper bound for the maximum achievable density is 20 Tbit/inch2 for a bit error rate target of 10−2.
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