Dynamic strain aging in the intermediate temperature regime of near-α titanium alloy, IMI 834: Experimental and modeling

A dynamic strain aging (DSA) regime is established for a near-a titanium alloy with a microstructure consisting of 80% equiaxed alpha, 15% lamellar alpha and 5% beta with silicon in solid solution through a series of constant strain rate tests carried out in tension from 5 x 10(-2) to 5 x 10(-6) s(-1) in the temperature range of 623-823 K. Transmission electron microscopy shows jogged screw dislocations within slip bands dominating the dislocation structure in this domain. Strain accumulation occurs by conservative jog glide along the length of screw dislocations due to line tension forces. We estimate the solute concentration accumulating at these edge jogs on arrest during their thermally activated glide over static solute obstacles. The domain of DSA is then predicted using Friedel's model to obtain the stress required to break the jogs free from the solute atmosphere. There is a good agreement between model and experimental data showing a DSA peak in the temperature range of 673-723 K. The solute species responsible for DSA from the model are C and Si, but dominated by C in this temperature and strain rate regime. Atom probe tomography demonstrates C and Si segregation at the dislocations, strongly supporting the model. (C) 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Automated summary

A dynamic strain aging (DSA) regime is established in a near-a titanium alloy through constant strain rate tests, with jogged screw dislocations dominating the dislocation structure within slip bands. The model predicts a DSA peak at 673-723K, with C and Si as solute species responsible for DSA, but dominated by C in this temperature and strain rate regime. Atom probe tomography confirms C and Si segregation at the dislocations, supporting the model.