Modeling hydrogen transport by dislocations

Mohsen Dadfarnia; May L. Martin; Akihide Nagao; Petros Sofronis; Ian M. Robertson

doi:10.1016/j.jmps.2015.03.002

Modeling hydrogen transport by dislocations

Mohsen Dadfarnia, May L. Martin, Akihide Nagao, Petros Sofronis, Ian M. Robertson

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144 Citations (Scopus)

Abstract

Recent experimental studies of the microstructure beneath fracture surfaces of specimens fractured in the presence of high concentrations of hydrogen suggest that the dislocation structure and hydrogen transported by mobile dislocations play important roles in establishing the local conditions that promote failure. The experiments demonstrate that hydrogen is responsible for the copious plasticity in large volumes of material before the onset of fracture and further afield from a crack tip. A revised model for hydrogen transport that accounts for hydrogen carried by dislocations along with stress driven diffusion and trapping at other microstructural defects is proposed. With the use of this new model, numerical simulation results for transient hydrogen profiles in the neighborhood of a crack tip are presented. Based on hydrogen-enhanced dislocation mobility and density, the results indicate that dislocation transport can contribute to the elevation of the local hydrogen concentrations ahead of the crack to levels above those predicted by the classical diffusion model and to distributions that extend farther afield.

Original language	English
Pages (from-to)	511-525
Number of pages	15
Journal	Journal of the Mechanics and Physics of Solids
Volume	78
DOIs	https://doi.org/10.1016/j.jmps.2015.03.002
Publication status	Published - Dec 15 2014

All Science Journal Classification (ASJC) codes

Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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10.1016/j.jmps.2015.03.002

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title = "Modeling hydrogen transport by dislocations",

abstract = "Recent experimental studies of the microstructure beneath fracture surfaces of specimens fractured in the presence of high concentrations of hydrogen suggest that the dislocation structure and hydrogen transported by mobile dislocations play important roles in establishing the local conditions that promote failure. The experiments demonstrate that hydrogen is responsible for the copious plasticity in large volumes of material before the onset of fracture and further afield from a crack tip. A revised model for hydrogen transport that accounts for hydrogen carried by dislocations along with stress driven diffusion and trapping at other microstructural defects is proposed. With the use of this new model, numerical simulation results for transient hydrogen profiles in the neighborhood of a crack tip are presented. Based on hydrogen-enhanced dislocation mobility and density, the results indicate that dislocation transport can contribute to the elevation of the local hydrogen concentrations ahead of the crack to levels above those predicted by the classical diffusion model and to distributions that extend farther afield.",

author = "Mohsen Dadfarnia and Martin, {May L.} and Akihide Nagao and Petros Sofronis and Robertson, {Ian M.}",

note = "Funding Information: The authors gratefully acknowledge the support of the International Institute for Carbon Neutral Energy Research (WPI-I2CNER), sponsored by the World Premier International Research Center Initiative (WPI) , MEXT, Japan. M.D. and P.S. also acknowledge discussions with Professor C. Pantano-Rubino on the numerical simulations. I. M. R. acknowledges support from the National Science Foundation through Award No. CMMI-1406462. Publisher Copyright: {\textcopyright} 2015 Elsevier Ltd.",

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doi = "10.1016/j.jmps.2015.03.002",

language = "English",

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AU - Dadfarnia, Mohsen

AU - Martin, May L.

AU - Nagao, Akihide

AU - Sofronis, Petros

AU - Robertson, Ian M.

N1 - Funding Information: The authors gratefully acknowledge the support of the International Institute for Carbon Neutral Energy Research (WPI-I2CNER), sponsored by the World Premier International Research Center Initiative (WPI) , MEXT, Japan. M.D. and P.S. also acknowledge discussions with Professor C. Pantano-Rubino on the numerical simulations. I. M. R. acknowledges support from the National Science Foundation through Award No. CMMI-1406462. Publisher Copyright: © 2015 Elsevier Ltd.

PY - 2014/12/15

Y1 - 2014/12/15

N2 - Recent experimental studies of the microstructure beneath fracture surfaces of specimens fractured in the presence of high concentrations of hydrogen suggest that the dislocation structure and hydrogen transported by mobile dislocations play important roles in establishing the local conditions that promote failure. The experiments demonstrate that hydrogen is responsible for the copious plasticity in large volumes of material before the onset of fracture and further afield from a crack tip. A revised model for hydrogen transport that accounts for hydrogen carried by dislocations along with stress driven diffusion and trapping at other microstructural defects is proposed. With the use of this new model, numerical simulation results for transient hydrogen profiles in the neighborhood of a crack tip are presented. Based on hydrogen-enhanced dislocation mobility and density, the results indicate that dislocation transport can contribute to the elevation of the local hydrogen concentrations ahead of the crack to levels above those predicted by the classical diffusion model and to distributions that extend farther afield.

AB - Recent experimental studies of the microstructure beneath fracture surfaces of specimens fractured in the presence of high concentrations of hydrogen suggest that the dislocation structure and hydrogen transported by mobile dislocations play important roles in establishing the local conditions that promote failure. The experiments demonstrate that hydrogen is responsible for the copious plasticity in large volumes of material before the onset of fracture and further afield from a crack tip. A revised model for hydrogen transport that accounts for hydrogen carried by dislocations along with stress driven diffusion and trapping at other microstructural defects is proposed. With the use of this new model, numerical simulation results for transient hydrogen profiles in the neighborhood of a crack tip are presented. Based on hydrogen-enhanced dislocation mobility and density, the results indicate that dislocation transport can contribute to the elevation of the local hydrogen concentrations ahead of the crack to levels above those predicted by the classical diffusion model and to distributions that extend farther afield.

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JO - Journal of the Mechanics and Physics of Solids

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Modeling hydrogen transport by dislocations

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