On the activation energy of high temperature creep in metals
- 1 May 1957
- journal article
- research article
- Published by Taylor & Francis in Philosophical Magazine
- Vol. 2 (17) , 584-588
- https://doi.org/10.1080/14786435708242699
Abstract
The temperature dependence of the activation volume or ‘stress-concentration factor’ q appearing in the expression relating the equilibrium tensile creep rate dε/dt, the temperature T and the applied tensile strew σ has been studied in the case of several pure metals subject to creep above about 1/2 T m, where T m, is the melting point. On writing q=nb 3, where b is the distance of closest approach of atom in the lattice, the relation was found to be valid in all cases, with Q=αT m, and α=4.9 (cal/g atm)/°K, i.e. Q is equal to about twice the latent heat of melting. The increase of q with temperature is ascribed to the increase in the mean spacing between adjacent logs in screw dislocations, and Q appears to be the activation energy for the conservative motion of jogs along dislocations. In face-centred cubic metals large values of n 0 are found to be associated with low stacking fault energies, and vice versa.Keywords
This publication has 6 references indexed in Scilit:
- On the Mechanism of High-Temperature Creep in Metals with Special Reference to Polycrystalline LeadProceedings of the Physical Society. Section B, 1956
- CXXXII. The generation of lattice defects by moving dislocations, and its application to the temperature dependence of the flow-stress of F.C.C. crystalsJournal of Computers in Education, 1955
- CXXX. On the linear work hardening mate of face-centred cubic single crystalsJournal of Computers in Education, 1955
- The Plastic Flow of Iron and Plain Carbon Steels above the A3-PointProceedings of the Physical Society. Section B, 1953
- The rate of viscous flow of metals. Part 2: leadProceedings of the Physical Society, 1939
- The rate of viscous flow of metals: Part 1, tinProceedings of the Physical Society, 1938