TY - JOUR
T1 - Thermodynamic and kinetic aspects of interfacial decohesion
AU - Mishin, Y.
AU - Sofronis, P.
AU - Bassani, J. L.
N1 - Funding Information:
The authors are grateful to C. J. McMahon and V. Vitek for useful discussions. Y. M. wishes to thank the Office of Basic Energy Sciences, US Department of Energy (BES/DOE) for financial support under Grant No. DE-FG02-01ER45871. Likewise, P S. is grateful to BES/DOE for financial support under Grant No. DE-FG02-96ER4539. J. L. B. is grateful to the National Science Foundation for support under Grant No. CMS 99-00131.
PY - 2002/8/16
Y1 - 2002/8/16
N2 - Thermodynamic and kinetic aspects of interfacial decohesion are analyzed for a uniformly stressed interface in the presence of an embrittling impurity. During the interfacial separation, the impurity penetrates into the interface and reduces it cohesion. Rice (1976) and Hirth and Rice (1980) analyzed the thermodynamics of this process in great detail with emphasis on the limiting cases of infinitely fast and infinitely slow separation. The 'dynamic' model of decohesion proposed in this work extends their analysis to an arbitrary relation between the rates of separation and impurity transport to the interface, including transient kinetics in which the two rates are comparable to one another. Such kinetics play an important role in the phenomenon of dynamic embrittlement observed in many materials. Calculations of dynamic decohesion have been performed for two mechanisms of impurity supply to the interface: the reaction kinetics and bulk diffusion. In both cases a kinetic parameter R has been identified such that R ≪ 1 for slow separation, R ≫ 1 for fast separation, and R ∼ 1 for the transient regime. In the transient regime, the work of decohesion, cohesive strength, the impurity concentration at the new surfaces, and other properties dend sensitively on the strain rate in agreement with experimental observations of dynamic embrittlement.
AB - Thermodynamic and kinetic aspects of interfacial decohesion are analyzed for a uniformly stressed interface in the presence of an embrittling impurity. During the interfacial separation, the impurity penetrates into the interface and reduces it cohesion. Rice (1976) and Hirth and Rice (1980) analyzed the thermodynamics of this process in great detail with emphasis on the limiting cases of infinitely fast and infinitely slow separation. The 'dynamic' model of decohesion proposed in this work extends their analysis to an arbitrary relation between the rates of separation and impurity transport to the interface, including transient kinetics in which the two rates are comparable to one another. Such kinetics play an important role in the phenomenon of dynamic embrittlement observed in many materials. Calculations of dynamic decohesion have been performed for two mechanisms of impurity supply to the interface: the reaction kinetics and bulk diffusion. In both cases a kinetic parameter R has been identified such that R ≪ 1 for slow separation, R ≫ 1 for fast separation, and R ∼ 1 for the transient regime. In the transient regime, the work of decohesion, cohesive strength, the impurity concentration at the new surfaces, and other properties dend sensitively on the strain rate in agreement with experimental observations of dynamic embrittlement.
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U2 - 10.1016/S1359-6454(02)00165-9
DO - 10.1016/S1359-6454(02)00165-9
M3 - Article
AN - SCOPUS:0037119082
SN - 1359-6454
VL - 50
SP - 3609
EP - 3622
JO - Acta Materialia
JF - Acta Materialia
IS - 14
ER -