Fig. 11.9 Corrosion rates of austenitic stainless steels and ferritic steels as a function of metal temperature and flue gas temperatures. Source: Ref 11 More

Fig. 4.21 Variation of stress with strain in ferritic steels containing carbon or nitrogen in solution. (a) The effect of removing and immediately reapplying the stress. (b) The effect of removing the stress and reapplying it after aging for a period of time at room or slightly elevated More

Fig. 8.2 Steam-side scale formation for 1–3% chromium ferritic steels correlated with the Larson–Miller parameter. Source: Ref 8.10 More

Fig. 4.26. Effect of ductility on endurance of ferritic steels ( Ref 20 ). More

Fig. 8.12. Thermal conductivities of iron, chromium, ferritic steels, and austenitic alloys ( Ref 51 ). More

Fig. 21.44 Microhardness profiles in various types of steels after gaseous ferritic nitrocarburizing (Nitemper process). Source: Ref 21.78 More

Fig. 1.12 Family relationships for standard ferritic stainless steels More

Fig. 40 Microstructure of two ferritic stainless steels. (a) Type 409 (UNS number S40900) muffler-grade strip in annealed condition. (b) Type 430 (UNS number S43000) annealed strip More

Fig. 7.7 Impact strength of three ferritic stainless steels as a function of sintering temperature and sintered density. Sintering atmosphere was hydrogen, and sintering time was 30 min. Source: Ref 16 . Reprinted with permission from MPIF, Metal Powder Industries Federation, Princeton, NJ More

Fig. 1 Family relationships for standard SAE ferritic stainless steels More

Fig. 2 Family relationships for standard AlSl ferritic stainless steels More

Fig. 11.12 Metal loss as a function of exposure time for 12Cr ferritic steel and three austenitic stainless steels. Source: Ref 15 More

Figure 8.12 The grain-size effect on fracture toughness of a ferritic steel at various temperatures in the brittle, subtransition temperature range. More

Fig. 8.5 Hall-Petch relationship for low-carbon ferritic steel. Source: Ref 8.3 More

Fig. 8.6 Microstructure of ultralow-carbon ferritic steel. Source: Ref 8.4 as published in Ref 8.3 More

Fig. 3.24. Creep-crack-growth behavior of ferritic steel base metal ( Ref 149 ). More

Fig. 5.6. Temperature dependence of fire-side corrosion for 2¼Cr-1Mo ferritic steel and type 321 austenitic stainless steel ( Ref 6 ). More

Fig. 2.27 Fracture surface from a ferritic steel (Fe-0.01C-0.24Mn-0.02Si, heat treated at 950 °C for ½ h, air cooled). The fracture was generated by impact at −196 °C (−321 °F). Cleavage steps beginning at the twin at top form a sharply defined river pattern. The arrow indicates crack More

Fig. 10.4 Hall-Petch relationship for low-carbon ferritic steel More