Search Results for phase composition

Fig. 6 Graphic illustrating the phase composition of a typical LPS WHA. Phase contrast provided by relief polishing and selective focus in brightfield, eliminating the need for chemical etching More

Source: E.K. Zakharov and B.G. Livshits, Phase Composition Diagram of the Cobalt-Chromium-Titanium Ternary System, Russ. Metall. Fuels , 1962, p 88–97 ( Ref 3 ) More

Source: E.K. Zakharov and B.G. Livshits, Phase Composition Diagram of the Cobalt-Chromium-Titanium Ternary System, Russ. Metall. Fuels , 1962, p 88–97 ( Ref 3 ) More

Fig. 22 Schematic representation of lamellar arrangement in a two-phase composite material. Source: Ref 19 More

Fig. 1 Phase diagrams for beryllium-copper alloys. (a) Binary composition for high-strength alloys such as C17200. (b) Pseudobinary composition for C17510, a high-conductivity alloy More

Fig. 21 Model binary phase diagram showing the composition and sintering temperature associated with liquid phase sintering in the L + S 2 phase field. The favorable characteristics for liquid phase sintering include a suppression of the melting temperature, high solid solubility More

Fig. 6 Left corner of a phase diagram. C E , eutectic composition; C L , composition of liquid; C S , composition of solid; C SM , maximum solubility in solid; T *, interface temperature; T L , liquidus temperature; T S , solidus temperature More

Fig. 17 Path of composition change of the liquid L and solid α phase during the freezing of a solid-solution alloy. Adapted from Ref 3 More

Fig. 3 Aluminum corner of the aluminum-copper phase diagram. Eutectic composition (not shown) is at 33 wt% (17 at.%) Cu. More

Fig. 1 Phase diagrams for copper-beryllium alloys. (a) Binary composition for high-strength alloys such as C17200. (b) Pseudobinary composition for C17510, a high-conductivity alloy More

Fig. 4 Phase diagrams for beryllium-copper alloys. (a) Binary composition for high-strength alloys such as C17200. (b) Pseudobinary composition for C17510, a high-conductivity alloy containing Cu-1.8Ni-0.4Be More

Fig. 20 Hypothetical phase diagram of system A-B, showing the composition of the solid as a 30% B alloy freezes. Adapted from Ref 17 More

Fig. 99 Composition profiles at manganese segregation in a dual-phase steel. (a) Profile obtained at low resolution showing manganese partitioning between austenite (martensite) and ferrite. (b) A high-resolution profile across the same boundary showing strong manganese segregation. Source More

Fig. 26 The copper-zinc phase diagram, showing the composition range for five common brasses. Source: adapted from Ref 7 More

Fig. 28 The aluminum-copper phase diagram, showing the composition range for the 2 xxx series of precipitation-hardenable aluminum alloys. Source: Ref 7 More

Fig. 5 Phase diagrams for beryllium-copper alloys. (a) Binary composition for high-strength alloys such as C17200. (b) Pseudobinary composition for C17510, a high-conductivity alloy More

Fig. 5 Illustration that the average composition in a two-phase region determines the composition of each phase via the tie-line ends More

Fig. 7 Diffusion path and composition vector for a single-phase diffusion couple plotted on a phase diagram. Open circles are the initial diffusion-couple alloys. More

Fig. 14 Calculated phase diagram of aluminum-zinc. (a) Temperature vs. composition. (b) Temperature vs. chemical potential of zinc. (c) Reciprocal of temperature vs. log 10 ( p Zn ). (d) Enlarged schematic diagram depicting the invariant equilibria shown in (c). fcc, face-centered cubic; hcp More

Fig. 6 Aluminum corner of the aluminum-copper phase diagram. Eutectic composition (not shown) is at 33.2 wt% (17 at.%) Cu. Source: Ref 8 More