Viscoelastic Behavior of Polymer Films During Scratch Test: a Quantitative Analysis

Vincent D. Jardret; Warren C. Oliver

doi:10.1557/PROC-594-251

Abstract

Dynamic properties of polymer surfaces affect their ability to withstand abrasive actions. Kinetic conditions, like velocity, penetration depth and shape of the abrasive particles, change the abrasion mechanisms and the morphology of the abraded surface. Using the scratch technique, along with profilometry measurement across the scratches, we have been able to completely characterize the residual scratch morphology. Pile-up deformation and visco-plastic relaxation are key phenomena that characterize the importance of ductility in the scratch resistance of polymer surfaces. Cross profilometry aids in studying the relaxation of the scratch morphology for different time and temperature history after the scratch is made. The effect of scratch velocity, penetration depth and indenter geometry on the contact pressure and friction coefficient estimated during a scratch test can also be analyzed. Following Eyring's law, a good correlation, was found between normal indentation and scratch testing in the evolution of the contact pressure with the applied strain rate. This work results in a better understanding of the stresses and the strains applied by an abrasive particle, and especially relates the dynamic mechanical properties of viscous materials, like stress exponent, to their scratch behavior. The method presented can provide for the measurement of dynamic properties of polymer surfaces or thin films under a very large range of strain rates.

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Article contents

Viscoelastic Behavior of Polymer Films During Scratch Test: a Quantitative Analysis

Abstract

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References

REFERENCES

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Viscoelastic Behavior of Polymer Films During Scratch Test: a Quantitative Analysis

Abstract

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References

REFERENCES

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