Creep curves for the 0.10wt% Ti CLAM steels fabricated by different tempering processes at 600°C/170 MPa. The creep curve for the steel without Ti addition is also shown for comparison.

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Creep curves for the 0.10wt% Ti CLAM steels fabricated by different tempering processes at 600°C/170 MPa. The creep curve for the steel without Ti addition is also shown for comparison.

2021, vol.28,no.3,pp.335-348.

Strengthening mechanisms of reduced activation ferritic/martensitic steels: A review .

Figures of the Article

Schematic of microstructures in the tempered RAFM steel.
Schematic of grain boundary sliding during high-temperature creep.
Subgrains and dislocation wall observed by Kassner in a 304 stainless steel [55]. Reprinted from Mater. Sci. Eng. A, 410-411, M.E. Kassner, Recent developments in understanding the mechanism of five-power-law creep, 20, Copyright 2005, with permission from Elsevier.
Schematic of stress state at a subgrain boundary.
Schematic of dislocation motion and vacancy migration in the steel during irradiation: (a) without MX carbides; (b) with MX carbides.
Typical high-temperature creep curve of the RAFM steel.
Comparison of high-temperature creep strength at 650°C (a) and irradiation resistance at 450–480°C (b) between ODS and RAFM steels in recent years.
Schematic of the preparation processes of ODS steels [104]. Reprinted from J. Nucl. Mater., 518, T. Jaumier, S. Vincent, L. Vincent, and R. Desmorat, Creep and damage anisotropies of 9%Cr and 14% Cr ODS steel cladding, 274, Copyright 2019, with permission from Elsevier.
Creep properties of cold deformation and thermal deformation-strengthened steels compared with typical Eurofer 97and F82H steels.
Schematic of the microstructural variation in RAFM steel under thermo-mechanical treatment (TMT).
Engineering stress–strain plots for the 0.10wt% Ti CLAM steels via different tempering processing at 600°C. The stress–strain curve for the steel without Ti addition is also shown for comparison.
Creep curves for the 0.10wt% Ti CLAM steels fabricated by different tempering processes at 600°C/170 MPa. The creep curve for the steel without Ti addition is also shown for comparison.

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