Compressive stress effects on nanoparticle modulus and fracture

W. M. Mook, J. D. Nowak, C. R. Perrey, C. B. Carter, R. Mukherjee, S. L. Girshick, P. H. McMurry, and W. W. Gerberich

Phys. Rev. B 75, 214112 – Published 22 June 2007

Abstract

Individual nanoparticles of silicon and titanium having diameters in the range of $40 - 140 nm$ have been repeatedly compressed by a nanoindenter. Even at low loads, the small tip-particle and particle-substrate contacts generate extreme pressures within the confined particle, influencing its stiffness and fracture toughness. The effect of these high pressures on the measured modulus is taken into account by invoking a Murnaghan equation-of-state-based analysis. Fracture toughness of the silicon particles is found to increase by a factor of 4 in compression for a $40 − nm$ -diam particle when compared to bulk silicon. Additionally, strain energy release rates increase by more than an order of magnitude for particles of this size when compared to bulk Si.

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Received 24 October 2006

DOI:https://doi.org/10.1103/PhysRevB.75.214112

Authors & Affiliations

W. M. Mook¹, J. D. Nowak¹, C. R. Perrey¹, C. B. Carter¹, R. Mukherjee², S. L. Girshick², P. H. McMurry², and W. W. Gerberich¹

¹Chemical Engineering and Materials Science, 151 Amundson Hall, University of Minnesota, Minneapolis, Minnesota 55455, USA
²Mechanical Engineering, 111 Church Street, University of Minnesota, Minneapolis, Minnesota 55455, USA

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Issue

Vol. 75, Iss. 21 — 1 June 2007

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