Fig. 4 Effect of alloy composition (high alloy versus low alloy concentrations of iron, silicon, manganese, and sulfur taken collectively) on the cracking tendency of postweld heat-treated René 41. Source: Ref 4 More

Fig. 5 Mechanical properties of a forged 34% Ni alloy. Alloy composition: 0.25 C, 0.55 Mn, 0.27 Si, 33.9 Ni, bal Fe. Heat treatment: annealed at 800 °C (1475 °F) and furnace cooled. More

Fig. 7 Mechanical properties of a forged 34% Ni alloy. Alloy composition: 0.25 C, 0.55 Mn, 0.27 Si, 33.9 Ni, balance Fe. Heat treatment: annealed at 800 °C (1475 °F) and furnace cooled More

Fig. 26 Schematic showing the effect of alloy composition, Δ t 8-5 , oxygen content, and γ grain size on the development of microstructure in ferritic steel weld metals. The hexagons represent cross sections of columnar γ grains. (a) The γ grain boundaries become decorated first More

Fig. 2 Influence of alloy composition on fluidity in lead-tin alloys. Source: Ref 2 More

Fig. 4 Influence of alloy composition on hot tearing susceptibility in aluminum-copper alloys. Source: Ref 2 More

Fig. 6 Black-box modeling. (a) Direct link from alloy composition and processing to product properties. (b) Determining product properties from alloy composition and processing via prediction of microstructure. (c) Using internal state variables to link chemical composition and processing More

Fig. 41 Effect of alloy composition on threshold stress. Effect is shown by relation of applied stress to average time to fracture for two 18-8 stainless steels (types 304 and 304L) and two high-alloy stainless steels (types 310 and 314) in boiling 42% magnesium chloride solution. More

Fig. 21 Schematic showing the effect of alloy composition, Δ t 8−5 , oxygen content, and γ grain size on the development of microstructure in ferritic steel weld metals. The hexagons represent cross sections of columnar γ grains. (a) The γ grain boundaries become decorated first More

Fig. 7 Effects of alloy composition on microstructure, crystal structure, and properties of quenched uranium alloys More

Fig. 5 Prealloyed randomly shaped powder particles of Ti-6Al-4V alloy composition. (a) As produced by the CSIRO process. Courtesy of CSIRO, Australia. (b) As produced by magnesium reduction of a mixture of TiCl 4 -ALCl 4 -VCl 4 in a continuous flow reactor. Courtesy of MER Corporation More

Fig. 11 Limit drawing ratios in dependence on alloy composition. d 0 =50 mm (2 in.). Source: Ref 18 More

Fig. 15 Use of a neural-network model for optimization of alloy composition in the Ti-Al-Fe system to maximize room-temperature yield strength More

Fig. 20 Illustration of the effect of steel alloy composition on Jominy hardenability for different alloys with the same nominal carbon content More

Fig. 47 Effect of alloy composition on stress-corrosion cracking resistance of mill-annealed titanium alloys in aqueous 3.5% NaCl solution at 24 °C (75 °F). Source: Ref 172 More

Fig. 8 Effect of the chemical composition of a binary alloy on alloy viscosity. Source: Ref 2 More

Fig. 4 Solidifying microstructure of thermally managed Al-9%Cu alloy composite (a) with external cooling of graphite rod extending out of the melt and (b) without external cooling of the graphite rod More

Fig. 2 Performance of hardfacing powders with different alloying compositions. HSS, high-strength steel; SS, stainless steel More