To determine sets of miscibility data estimates for A 1 2 and A 2 1 in the Margules Equation Concept Introduction : Margules Equations are given as, γ 1 α = exp { x 2 α 2 × [ A 12 + 2 × ( A 21 − A 12 ) × x 1 α ] } γ 1 β = exp { x 2 β 2 × [ A 12 + 2 × ( A 21 − A 12 ) × x 1 β ] } x 2 α = 1 − x 1 α x 2 β = 1 − x 1 β Margules Equations for x 2 α , x 2 β are given as, γ 2 α = exp { x 1 α 2 × [ A 21 + 2 × ( A 12 − A 21 ) × x 2 α ] } γ 2 β = exp { x 1 β 2 × [ A 21 + 2 × ( A 12 − A 21 ) × x 2 β ] }

Question

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Answer 1

Question

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

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Answer 2

Question

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

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Answer 3

Question

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

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Answer 4

Question

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

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Answer 5

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

Answer 6

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

Answer 7

Chapter 15, Problem 15.2P

(a)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

Answer 8

(a)

Expert Solution

Answer to Problem 15.2P

A₂₁ = 2.747

A₁₂ = 2.747

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.9x2β=1−x1β=0.1

Now let’s guess: A₁₂ = 2

and

A₂₁ = 2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[9exp{0.01A12+0.018×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[9]+0.01A12+0.018A21−0.018A12

0.656A12+0.144A21=ln[9]

... Equation (A)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[9exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[9]+0.01×A21+0.018A12−0.018A21=0.81A21+0.162A12−0.162A21

ln[9]=0.144A12+0.656A21

...Equation (B)

Now solving Equation (A) and (B), we get

A₂₁ = 2.747

A₁₂ = 2.747

Answer 13

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

Answer 14

(b)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

Answer 15

(b)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.148

A₂₁ = 2.781

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

x1α=0.2x2α=1−x1α=0.8x1β=0.9x2β=1−x1β=0.1

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.2exp{0.82×[A12+2×(A21−A12)×0.2]}=0.9exp{0.12×[A12+2×(A21−A12)×0.9]}

ln[exp{0.64×A12+0.256×(A21−A12)}]=ln[4.5exp{0.01A12+0.018×(A21−A12)}]

0.64×A12+0.256A21−0.256A12=ln[4.5]+0.01A12+0.018A21−0.018A12

0.392A12+0.238A21=ln[4.5]

... Equation (C)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.8exp{0.22×[A21+2×(A12−A21)×0.8]}=0.1exp{0.92×[A21+2×(A12−A21)×0.1]}

ln[8exp{0.04×A21+0.064×(A12−A21)}]=ln[exp{0.81A21+0.162×(A12−A21)}]

ln[8]+0.04×A21+0.064A12−0.064A21=0.81A21+0.162A12−0.162A21

ln[8]=0.098A12+0.672A21

...Equation (D)

Now solving Equation (C) and (D), we get

A₁₂ = 2.148

A₂₁ = 2.781

Answer 20

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

Answer 21

(c)

Interpretation Introduction

Interpretation:

To determine sets of miscibility data estimates for A₁₂ and A₂₁ in the Margules Equation

Concept Introduction:

Margules Equations are given as,

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

x2α=1−x1αx2β=1−x1β

Margules Equations for x2α,x2β are given as,

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

Answer 22

(c)

Expert Solution

Answer to Problem 15.2P

A₁₂ = 2.781

A₂₁ = 2.148

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

x1α=0.1x2α=1−x1α=0.9x1β=0.8x2β=1−x1β=0.2

γ1α=exp{x2α2×[A12+2×(A21−A12)×x1α]}

γ1β=exp{x2β2×[A12+2×(A21−A12)×x1β]}

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

As given below:

x1α×γ1α=x1β×γ1β

x1αexp{x2α2×[A12+2×(A21−A12)×x1α]}=x1βexp{x2β2×[A12+2×(A21−A12)×x1β]}

0.1exp{0.92×[A12+2×(A21−A12)×0.1]}=0.8exp{0.22×[A12+2×(A21−A12)×0.8]}

ln[exp{0.81×A12+0.162×(A21−A12)}]=ln[8exp{0.04A12+0.064×(A21−A12)}]

0.81×A12+0.162A21−0.162A12=ln[8]+0.04A12+0.064A21−0.064A12

0.672A12+0.098A21=ln[8]

... Equation (E)

γ2α=exp{x1α2×[A21+2×(A12−A21)×x2α]}

γ2β=exp{x1β2×[A21+2×(A12−A21)×x2β]}

x2α×γ2α=x2β×γ2β

x2αexp{x1α2×[A21+2×(A12−A21)×x2α]}=x2βexp{x1β2×[A21+2×(A12−A21)×x2β]}

0.9exp{0.12×[A21+2×(A12−A21)×0.9]}=0.2exp{0.82×[A21+2×(A12−A21)×0.2]}

ln[4.5exp{0.01×A21+0.018×(A12−A21)}]=ln[exp{0.64A21+0.256×(A12−A21)}]

ln[4.5]+0.01×A21+0.018A12−0.018A21=0.64A21+0.256A12−0.256A21

ln[4.5]=0.392A12+0.238A21

...Equation (F)

Now solving Equation (E) and (F), we get

A₁₂ = 2.781

A₂₁ = 2.148

Answer 27

Ch. 15 - Prob. 15.1P Ch. 15 - Prob. 15.2P Ch. 15 - Work Prob. 15.2 for the van Laar equation. 15.2. A...Ch. 15 - Consider a binary vapor-phase mixture described by...Ch. 15 - Prob. 15.5P Ch. 15 - It has been suggested that a value for GEof at...Ch. 15 - Pure liquid species 2 and 3 are for practical...Ch. 15 - It is demonstrated in Ex. 15.5 that the Wilson...Ch. 15 - Vapor sulfur hexafluoride SF6 at pressures of...Ch. 15 - Prob. 15.10P

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