Deformation in metals after low-temperature irradiation: Part I - Mapping macroscopic deformation modes on true stress-dose plane

Thak Sang Byun, Kenneth Farrell, Meimei Li

Research output: Contribution to journalArticlepeer-review

31 Scopus citations

Abstract

Macroscopic deformation modes, elastic, uniform plastic, and unstable plastic deformation modes, are mapped in tensile true stress-dose space for more than two dozen metallic materials consisting of 13 body-centered cubic (bcc), 11 face-centered cubic (fcc), and two hexagonal closed packed (hcp) metals. The boundaries between different deformation zones are set by the true stress versus dose curves: the yield stress (YS), plastic instability stress (PIS), and true fracture stress (FS) plotted as functions of dose. Values for these true stresses are obtained from uniaxial tensile tests or calculated from engineering tensile data using a linear strain-hardening model for necking deformation. The relatively low-strength annealed fcc metals display large uniform plasticity regions, while unstable deformation regions are dominant in the harder bcc and hcp metals. PIS values for all materials are independent of dose except for the precipitation-hardened IN718 alloy, where a decrease of PIS occurs due to an irradiation-induced change in second phases. In the bcc materials for high-temperature application, such as 9Cr ferritic/martensitic steels, sintered molybdenum, vanadium, and tantalum, the radiation-induced embrittlement is characterized in terms of FS decreasing with dose at relatively high doses. FS is nearly dose-independent below the critical dose for embrittlement. It is concluded that the tensile stress-based deformation mode maps effectively integrate mechanical property information and characterize differences in radiation effects between crystalline structures or material groups.

Original languageEnglish
Pages (from-to)1044-1055
Number of pages12
JournalActa Materialia
Volume56
Issue number5
DOIs
StatePublished - Mar 2008

Funding

This research was sponsored by US Department of Energy, Offices of Fusion Energy Sciences and Basic Energy Science, under Contract DE-AC05-00OR22725 with UT-Battelle, LLC. The authors express special thanks to Drs. R.L. Klueh and J. T. Busby for technical reviews and thoughtful comments.

FundersFunder number
Fusion Energy Sciences and Basic Energy ScienceDE-AC05-00OR22725
U.S. Department of Energy

    Keywords

    • Deformation mode maps
    • Fracture stress
    • Irradiation effect
    • Metallic materials
    • Plastic instability stress

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