For alloys of two hypothetical metals A and B, there exist an a, A-rich phase and a ß, B-rich phase.From the mass fractions of both phases for two different alloys (given below), which are at the same temperature, determinethe composition of the phase boundary (or solubility limit) for the following:Fraction FractionAlloy Compositiona PhaseB Phase60 wt% A - 40 wt% B0.590.4130 wt% A - 70 wt% B0.130.87(a) a phasewt% A(b) B phasewt% A

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For alloys of two hypothetical metals A and B, there exist an a, A-rich phase and a ß, B-rich phase. From the mass fractions of both phases for two different alloys (given below), which are at the same temperature, determin the composition of the phase boundary (or solubility limit) for the following: Fraction Fraction Alloy Composition a Phase B Phase 60 wt% A - 40 wt% B 0.59 0.41 30 wt% A - 70 wt% B 0.13 0.87

For alloys of two hypothetical metals A and B, there exist an a, A-rich phase and a ß, B-rich phase. From the mass fractions of both phases for two different alloys (given below), which are at the same temperature, determin the composition of the phase boundary (or solubility limit) for the following: Fraction Fraction Alloy Composition a Phase B Phase 60 wt% A - 40 wt% B 0.59 0.41 30 wt% A - 70 wt% B 0.13 0.87

Materials Science And Engineering Properties

1st Edition

ISBN:9781111988609

Author:Charles Gilmore

Publisher:Charles Gilmore

Chapter5: Phase Transformations And Phase Diagrams

Section: Chapter Questions

Problem 5.6P

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