Dissemination of IT for the Promotion of Materials Science (DoITPoMS)

DoITPoMS Teaching & Learning Packages Introduction to Mechanical Properties of Materials Going further
Introduction to Mechanical Properties of Materials AimsBefore you startIntroductionTensile test: force and extensionStress, strain and Poisson's ratioElastic deformation: Hooke's law and stiffnessViscoelasticityPlastic deformation: strength and ductilitySlip: resolved shear stress and Schmid factor, Taylor factorHardness and work hardeningCreepFracture: toughnessDuctile-brittle transition temperatureSummaryQuestionsGoing further
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Books

These textbooks gives a general introduction to mechanical behaviours:

  • W.F. Hosford, Mechanical Behaviour of Materials, 2010, Cambridge University Press
  • W.D. Callister, D.G. Rethwisch, Materials Science and Engineering: An Introduction, 2002, Wiley
  • M.F. Ashby and D.R.H. Jones, Engineering Materials: Introduction to their Properties and Applications, 1996, Pergamon

To explore time dependent response to an applied stress, as known as anelastcity, see:

  • A.S. Nowick, B.S. Berry, Anelastic Relaxation in Crystalline Solids, Academic Press, New York and London 1972

Websites

  • Tensors are a powerful tool for analysing mechanical states, see Tensors in Materials Science TLP.
  • For an important example of the application of tensors in stress analysis, see Stress Analysis and Mohr's Circle TLP.
  • There are other stress states, such as bending or torsion, see Bending and Torsion of Beams TLP.
  • For a more detailed description and analysis of tensile test and hardness test, see Mechanical Testing of Metals TLP.
  • To understand dislocations and work hardening further, see Mechanisms of Plasticity TLP.
  • To explore slip in single crystals in more details, see Slip in Single Crystals TLP.
  • Hardenability of a steel is a measure of the capacity of the steel to increase hardness and is measured by the Jominy end quench test. See The Jominy End Quench Test TLP.
  • To explore creep further, see Creep Deformation of Metals TLP.
  • In brittle fracture, the stress is larger at the crack tip. To describe this, we can introduce stress intensity factor K, from which we define the fracture toughness Kc in a specific geometry (the amount of stress required to propagate a preexisting flaw). See Brittle Fracture TLP.
  • In ductile fracture, the resistance to fracture can be improved by absorbing more energy before fracture, this process is called toughening. See Toughening TLP.

Other resources

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