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Chapter 18, Problem 30P
To determine

The change in entropy when a 27.9g of ice cube at 12°C is transformed into steam at 115°C .

Expert Solution & Answer
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Answer to Problem 30P

The change in entropy when a 27.9g of ice cube at 12°C is transformed into steam at 115°C is 244.5J/K .

Explanation of Solution

Given Info: The mass of the ice cube is 27.9g , the value of cold temperature is 12°C and the value of value of hot temperature is 115°C .

Formula to find change in entropy to transform ice at 12°C  to ice at 0°C  is,

ΔS1 =mCln(ThTc)

Here,

ΔS1 is the entropy change to transform ice at 12°C  to ice at 0°C .

m is the mass of ice.

Th is the hot temperature.

Tc is the cold temperature.

C is the specific heat of ice

Substitute 27.9g for m , 2.108J/gK for C , 0°C for Th and 12°C for Tc to find the change in entropy.

ΔS1=(27.9g×2.108J/gK×ln((273+0)K(27312)K))=(27.9×2.108×ln(273261))=2.64J/K

Thus, the change in the entropy to transform ice at 12°C to ice at 0°C is 2.64J/K .

Formula to find the change in entropy to transform ice at 0°C  to water at 0°C is,

ΔS2 =mLT1

Here,

ΔS2 is the entropy change to transform to transform ice at 0°C  to water at 0°C .

m is the mass of water.

T1 is the transition temperature from ice to water.

L is the latent heat of fusion

Substitute 27.9g for m , 334J/g for L and 0°C for T1 to find the change in entropy.

ΔS2=(27.9g×334J/g(273+0)K)=(27.9×344273)J/K=34.1J/K

Thus, the change in the entropy to transform ice at 0°C  to water at 0°C is 34.1J/K .

Formula to find change in entropy to transform water at 0°C to water at 100°C is,

ΔS3 =mCln(ThTc)

Here,

ΔS3 is the entropy change to transform water at 0°C to water at 100°C .

m is the mass of water.

C is the specific heat of water

Substitute 27.9g for m , 4.19J/gK for C , 100°C for Th and 0°C for Tc to find the change in entropy.

ΔS3=(27.9g×4.19J/gK×ln(273+100K273+0K))=(27.9×4.19×ln(373273))=36.46J/K

Thus, the change in the entropy to transform water at 0°C to water at 100°C is 36.46J/K .

Formula of find change in entropy to transform water at 100°C to steam at 100°C is,

ΔS4 =mLT2

Here,

ΔS4 is the entropy change to transform water at 100°C to steam at 100°C .

m is the mass of water.

T2 is the transition temperature from water to steam.

L is the latent heat of vaporization.

Substitute 27.9g for m , 2256J/g for L and 100°C for T2 to find the change in entropy.

ΔS4=(27.9g×2256J/g273+100K)=(27.9×2256373)J/K=168.7J/K

Thus, the change in the entropy to transform water at 100°C to steam at 100°C is 168.7J/K .

Formula to find change in entropy to transform steam at 100°C to steam at 115°C is,

ΔS5 =mCln(ThTc)

Here,

ΔS5 is the entropy change to transform steam at 100°C to steam at 115°C .

m is the mass of steam.

Th is the hot temperature.

Tc is the cold temperature.

C is the specific heat of steam

Substitute 27.9g for m , 1.99J/gK for C , 115°C for Th and 100°C for Tc to find the change in entropy.

ΔS5=(27.9g×1.99J/gK×ln(273+115K273+100K))=(27.9×1.99×ln(388373))J/K=2.19J/K

Thus, the change in the entropy to transform steam at 100°C to steam at 115°C is 2.19J/K .

Formula to find the total change in entropy to transform ice at 12°C to steam at 115°C is,

ΔS=ΔS1+ΔS2+ΔS3+ΔS4+ΔS5

Substitute 2.64J/K for ΔS1 , 34.1J/K for ΔS2 , 36.46J/K for ΔS3 , 168.7J/K for ΔS4 and 2.19J/K for ΔS5 in above expression.

ΔS=2.64J/K+34.1J/K+36.46J/K+168.7J/K+2.19J/K=244.1J/K

Thus, the total change in the entropy is 244.1J/K .

Conclusion:

Therefore, the total change in the entropy is 244.1J/K .

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Chapter 18 Solutions

Bundle: Principles of Physics: A Calculus-Based Text, 5th + WebAssign Printed Access Card for Serway/Jewett's Principles of Physics: A Calculus-Based Text, 5th Edition, Multi-Term

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