Mechanisms of tempered martensite embrittlement in low alloy steels |
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Authors: | Horn R M Ritchie Robert O |
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Affiliation: | (1) Department of Materials Science and Mineral Engineering, University of California, 94720 Berkeley, CA;(2) Department of Mechanical Engineering, Massachusetts Institute of Technology, 02139 Cambridge, MA |
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Abstract: | An investigation into the mechanisms of tempered martensite embrittlement (TME), also know as “500°F” or “350°C” or one-step
temper embrittlement, has been made in commercial, ultra-high strength 4340 and Si-modified 4340 (300-M) alloy steels, with
particular focus given to the role of interlath films of retained austenite. Studies were performed on the variation of i)
strength and toughness, and ii) the morphology, volume fraction and thermal and mechanical stability of retained austenite,
as a function of tempering temperature, following oil-quenching, isothermal holding, and continuous air cooling from the austenitizing
temperature. TME was observed as a decrease in bothK
Ic and Charpy V-notch impact energy after tempering around 300°C in 4340 and 425°C in 300-M, where the mechanisms of fracture
were either interlath cleavage or largely transgranular cleavage. The embrittlement was found to be concurrent with the interlath
precipitation of cementite during temperingand the consequent mechanical instability of interlath films of retained austenite during subsequent loading. The role of silicon
in 300-M was seen to retard these processes and hence retard TME to higher tempering temperatures than for 4340. The magnitude
of the embrittlement was found to be significantly greater in microstructures containing increasing volume fractions of retained
austenite. Specifically, in 300-M the decrease inK
Ic, due to TME, was a 5 MPa√m in oil quenched structures with less than 4 pct austenite, compared to a massive decrease of 70
MPa√m in slowly (air) cooled structures containing 25 pct austenite. A complete mechanism of tempered martensite embrittlement
is proposed involving i) precipitation of interlath cementite due to partial thermal decomposition of interlath films of retained
austenite, and ii) subsequent deformation-induced transformation on loading of remaining interlath austenite, destabilized
by carbon depletion from carbide precipitation. The deterioration in toughness, associated with TME, is therefore ascribed
to the embrittling effect of i) interlath cementite precipitates and ii) an interlath layer of mechanically-transformed austenite,i.e., untempered martensite. The presence of residual impurity elements in prior austenite grain boundaries, having segregated
there during austenitization, may accentuate this process by providing an alternative weak path for fracture. The relative
importance of these effects is discussed.
Formerly with the Lawrence Berkeley Laboratory, University of California. |
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