IRRADIATION INDUCED-HARDENING AND EMBRITTLEMENT OF REACTOR PRESSURE VESSEL STEELS AS REVEALED BY ATOMIC LEVEL SIMULATIONS
AlAsqalani, A. (2018). IRRADIATION INDUCED-HARDENING AND EMBRITTLEMENT OF REACTOR PRESSURE VESSEL STEELS AS REVEALED BY ATOMIC LEVEL SIMULATIONS. EKB Journal Management System, 18(18th International Conference on Applied Mechanics and Mechanical Engineering.), 1-1. doi: 10.21608/amme.2018.34968
A. T. AlAsqalani. "IRRADIATION INDUCED-HARDENING AND EMBRITTLEMENT OF REACTOR PRESSURE VESSEL STEELS AS REVEALED BY ATOMIC LEVEL SIMULATIONS". EKB Journal Management System, 18, 18th International Conference on Applied Mechanics and Mechanical Engineering., 2018, 1-1. doi: 10.21608/amme.2018.34968
AlAsqalani, A. (2018). 'IRRADIATION INDUCED-HARDENING AND EMBRITTLEMENT OF REACTOR PRESSURE VESSEL STEELS AS REVEALED BY ATOMIC LEVEL SIMULATIONS', EKB Journal Management System, 18(18th International Conference on Applied Mechanics and Mechanical Engineering.), pp. 1-1. doi: 10.21608/amme.2018.34968
AlAsqalani, A. IRRADIATION INDUCED-HARDENING AND EMBRITTLEMENT OF REACTOR PRESSURE VESSEL STEELS AS REVEALED BY ATOMIC LEVEL SIMULATIONS. EKB Journal Management System, 2018; 18(18th International Conference on Applied Mechanics and Mechanical Engineering.): 1-1. doi: 10.21608/amme.2018.34968

IRRADIATION INDUCED-HARDENING AND EMBRITTLEMENT OF REACTOR PRESSURE VESSEL STEELS AS REVEALED BY ATOMIC LEVEL SIMULATIONS

The International Conference on Applied Mechanics and Mechanical Engineering
Article 31, Volume 18, 18th International Conference on Applied Mechanics and Mechanical Engineering., April 2018, Page 1-1  XML PDF (35.88 K)
Document Type: Original Article
DOI: 10.21608/amme.2018.34968
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Author
A. T. AlAsqalani
Physics Department, Faculty of Science, Assiut University, 71516 Assiut, Egypt.
Abstract
ABSTRACT
The increase of computing power in recent years has made large scale simulation
with million, or even billion of atoms is possible. Computer simulations using classical
interatomic potentials are an efficient tool to study and understand materials
properties and to investigate processes of materials on the atomic level. In this
manner length and time scales can be considered which are often hardly accessible
by experiments. In the talk two different applications of atomistic simulations are
considered.
In the first topic the energetics and thermodynamics of the coherent copper
nanoclusters in bcc-Fe are obtained using a combination of on-lattice Monte Carlo
simulations and off-lattice molecular dynamics. These nanoclusters are assumed to
be the main cause of hardening and embrittlement of Cu-bearing reactor pressure
vessel steels since they act as obstacles to dislocation motion within the grains of the
polycrystalline bcc-Fe.
The second topic about the fracture of ferrite steels (structural materials for nuclear
fission reactors) during neutron irradiation in which the interaction between
embedded nanocluster and an edge crack in the framework of linear elastic fracture
mechanics (LEFM), are investigated at nanoscale using molecular static (MS)
simulations.
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