Title :
Thermal asperity trends
Author :
Stupp, Steven E. ; Baldwinson, Michael A. ; McEwen, Peter ; Crawford, T.M. ; Rogers, Charles T.
Author_Institution :
Quantum Corp., Milpitas, CA, USA
fDate :
3/1/1999 12:00:00 AM
Abstract :
A thermo-mechanical model that predicts the changes in thermal asperities as a function of increasing areal density is described. Conceptually, the problem is divided into two portions: the collision and relative motion of an asperity along the slider, and the subsequent diffusion of thermal energy into the head in the vicinity of the read element. The former is treated using a quasi-static spring model for the various mechanical degrees of freedom; the later with a scaling model for the heat transfer. The thermal model was verified by using a focused fast laser pulse to simulate a thermal transient at the read element. The predictions of the full model were also compared with measured thermal asperities that were produced on a spin-stand. The results support one of the model´s main predictions: a significant increase in the amplitude of worst case thermal asperity events can be expected in the next few years
Keywords :
magnetic heads; magnetoresistive devices; transients; areal density; focused fast laser pulse; magnetoresistive heads; quasi-static spring model; read element; scaling model; slider; spin-stand; thermal asperity trends; thermal transient; thermo-mechanical model; Anisotropic magnetoresistance; Giant magnetoresistance; Magnetic heads; Manufacturing; Physics; Predictive models; Springs; Temperature; Thermal resistance; Thermomechanical processes;
Journal_Title :
Magnetics, IEEE Transactions on
