Physical Models for Cleavage Fracture at Various Temperatures

Jian Hong Chen

doi:10.4028/www.scientific.net/KEM.353-358.28

Paper Titles

Interface Strength of Low-Dimensional Nano-Components
p.1

Metal Working and Dislocation Structures
p.9

Shape Prediction of Fatigue Crack Based on a Given Stress Intensity Factor Distribution
p.19

Fatigue Damage Accumulation of Welded Bridge Member during Crack Growth Propagation with Initial Crack
p.24

Physical Models for Cleavage Fracture at Various Temperatures
p.28

Study on Fracture Mechanisms of TiAl Alloys by In Situ Tensile Tests
p.34

Dynamic Analysis of Antiplane Crack under SH-Waves in the Functionally Graded Materials
p.38

Mode III Yoffe Dynamic Crack Problem on the Interface between Dissimilar Materials
p.42

Morphology Evolutions of the Short Fatigue Crack Propagation of 1Cr18Ni9Ti Weld Metal
p.46

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Physical Models for Cleavage Fracture at Various Temperatures

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Key Engineering Materials (Volumes 353-358)

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28-33

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https://doi.org/10.4028/www.scientific.net/KEM.353-358.28

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Online since:

September 2007

Authors:

Jian Hong Chen

Keywords:

Cleavage, HSLA Steel, Local Approach, Physical Model, Transition Temperature

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