TY - JOUR
T1 - The emergence of crack-like behavior of frictional rupture
T2 - Edge singularity and energy balance
AU - Barras, Fabian
AU - Aldam, Michael
AU - Roch, Thibault
AU - Brener, Efim A.
AU - Bouchbinder, Eran
AU - Molinari, Jean François
N1 - E.B. and J.-F.M. acknowledge support from the Rothschild Caesarea Foundation . E.B. acknowledges support from the Israel Science Foundation (Grant No. 295/16 ). J.-F.M., F.B. and T.R. acknowledge support from the Swiss National Science Foundation (Grant No. 162569 ). This research is made possible in part by the historic generosity of the Harold Perlman Family.
PY - 2020/2/1
Y1 - 2020/2/1
N2 - The failure of frictional interfaces — the process of frictional rupture — is widely assumed to feature crack-like properties, with far-reaching implications for various disciplines, ranging from engineering tribology to earthquake physics. An important condition for the emergence of a crack-like behavior is the existence of stress drops in frictional rupture, whose basic physical origin has been recently elucidated. Here we show that for generic and realistic frictional constitutive relations, and once the necessary conditions for the emergence of an effective crack-like behavior are met, frictional rupture dynamics are approximately described by a crack-like, fracture mechanics energy balance equation. This is achieved by independently calculating the intensity of the crack-like singularity along with its associated elastic energy flux into the rupture edge region, and the frictional dissipation in the edge region. We further show that while the fracture mechanics energy balance equation provides an approximate, yet quantitative, description of frictional rupture dynamics, interesting deviations from the ordinary crack-like framework — associated with non-edge-localized dissipation — exist. Together with the recent results about the emergence of stress drops in frictional rupture, this work offers a comprehensive and basic understanding of why, how and to what extent frictional rupture might be viewed as an ordinary fracture process. Various implications are discussed.
AB - The failure of frictional interfaces — the process of frictional rupture — is widely assumed to feature crack-like properties, with far-reaching implications for various disciplines, ranging from engineering tribology to earthquake physics. An important condition for the emergence of a crack-like behavior is the existence of stress drops in frictional rupture, whose basic physical origin has been recently elucidated. Here we show that for generic and realistic frictional constitutive relations, and once the necessary conditions for the emergence of an effective crack-like behavior are met, frictional rupture dynamics are approximately described by a crack-like, fracture mechanics energy balance equation. This is achieved by independently calculating the intensity of the crack-like singularity along with its associated elastic energy flux into the rupture edge region, and the frictional dissipation in the edge region. We further show that while the fracture mechanics energy balance equation provides an approximate, yet quantitative, description of frictional rupture dynamics, interesting deviations from the ordinary crack-like framework — associated with non-edge-localized dissipation — exist. Together with the recent results about the emergence of stress drops in frictional rupture, this work offers a comprehensive and basic understanding of why, how and to what extent frictional rupture might be viewed as an ordinary fracture process. Various implications are discussed.
U2 - https://doi.org/10.1016/j.epsl.2019.115978
DO - https://doi.org/10.1016/j.epsl.2019.115978
M3 - مقالة
SN - 0012-821X
VL - 531
JO - Earth and Planetary Science Letters
JF - Earth and Planetary Science Letters
M1 - 115978
ER -