EBK CHEMICAL PRINCIPLES
EBK CHEMICAL PRINCIPLES
8th Edition
ISBN: 9781305856745
Author: DECOSTE
Publisher: CENGAGE LEARNING - CONSIGNMENT
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Chapter 9, Problem 12DQ

(a)

Interpretation Introduction

Interpretation: The value of change in enthalpy, internal energy, heat and work done needs to be compared for two paths mentioned in the question.

Concept Introduction:

For a process at constant pressure, the work dome can be calculated as follows:

  w=PΔV

Also, value of heat, q can be calculated as follows:

  qP=nCPΔT

The change in enthalpy is equal to qP for constant pressure condition. The change in internal energy can be calculated s follows:

  ΔE=q+w

Here, q is heat and w is work done.

(a)

Expert Solution
Check Mark

Explanation of Solution

The initial and final values of pressure and volume are as follows:

  P1=1 atmP2=2 atmV1=1.0 LV2=2.0 L

Since, the changes occur in path then there are two paths possible for the changes.

In path 1: Initially, 1 L volume changes to 2 L and pressure remains the same that is 1 atm after that pressure changes from 1 atm to 2 atm and volume is 2 L.

In path 2: Initially, 1 atm pressure changes to 2 atm and volume remains the same that is 1 L. After that volume changes from 1 L to 2 L and pressure is 2 atm.

The enthalpy change and internal energy change does not depend on paths as they are state functions. Thus, for path 1 and path 2, the change in enthalpy and internal energy remains the same.

Heat and work are path functions because the values depend on path. Thus, values of q and w will not be same for path 1 and path 2.

In path 1, gas expands and change in volume takes place from 1 L to 2 L against a constant pressure of 1 atm but in second path, the expansion takes place against pressure 2 atm.

Due to the above reason, the work done in first path will be less than the second path. According to first law of thermodynamics, the change in internal energy, heat and work done are related to each other as follows:

  ΔE=q+w

Here, the value of change in internal energy is equal in both the paths and the value of w is higher in path 2 thus, the value of q should be lower in path 2.

(b)

Interpretation Introduction

Interpretation: The change in internal energy, change in enthalpy, heat and work done needs to be calculated for each case and if the calculation makes sense or not needs to be explained.

Concept Introduction:

For a process at constant pressure, the work dome can be calculated as follows:

  w=PΔV

Also, value of heat, q can be calculated as follows:

  qP=nCPΔT

The change in enthalpy is equal to qP for constant pressure condition. The change in internal energy can be calculated s follows:

  ΔE=q+w

Here, q is heat and w is work done.

(b)

Expert Solution
Check Mark

Explanation of Solution

If path 1 is considered, there are mainly 2 steps. In step 1, pressure is constant and change in volume from 1 L to 2 L takes place.

The work done for this step can be calculated as follows:

  w1=PΔV

Putting the values,

  w1=(1.0 atm)(21) L=1.0 L atm(101.325 J1 L atm)=101 J

Using the ideal gas equation,

  PΔV=nRΔTΔT=PΔVnR=1.01 JnR

At constant pressure,

  q1=ΔH=nCPΔT

Putting the values,

  q1=ΔH=nCPΔT

Putting the values,

  q1=ΔH=n(52R)(101 JnR)=253 J

The value of change in internal energy can be calculated as follows:

  ΔE1=nCVΔT=n(32R)(101 JnR)=152 J

Now, for step 2 in path 1, volume is constant and change in pressure takes place from 1 atm to 2 atm.

Since, the change in volume does not take place; the work done will be zero.

From the ideal gas law, the change in T can be calculated as follows:

  ΔT=ΔPVnR

Putting the values,

  ΔT=(21) atm(2 L)nR=(2 L atm)nR(101.325 J1 L atm)=203 JnR

The value of change in internal energy will be equal to q2

Thus,

  q2=ΔE2=nCVΔT=n(32R)(203 JnR)=304 J

Similarly,

  ΔH2=nCPΔT=n(52R)(203 JnR)=508 J

The total value of work done, heat, change in internal energy and change in enthalpy for first path will be:

  q=q1+q2=(253+304) J=557 J

Similarly,

  w=w1+w2=(101+0) J=101 J

Also,

  ΔE=ΔE1+ΔE2=(152+304) J=456 J

And,

  ΔH=ΔH1+ΔH2=(253+508) J=761 J

Now, considering path 2 there are also two parts.

In step 1 of the path 2:

Volume is constant and change in pressure takes place from 1 to 2 atm.

Thus, work done will be 0.

The change in temperature can be calculated as follows:

  ΔT=ΔPVnR

Putting the values,

  ΔT=(21) atm(1 L)nR=(1 L atm)nR(101.325 J1 L atm)=101.325 JnR

The value of change in internal energy will be equal to q3

Thus,

  q3=ΔE3=nCVΔT=n(32R)(101.325 JnR)=152 J

Similarly,

  ΔH3=nCPΔT=n(52R)(101.325 JnR)=253 J

Now, for step 2 of path 2:

The change in volume takes place from 1 to 2 L at constant pressure thus, work done will be:

  w4=PΔV=(2 L atm)(101.325 J1 L atm)=203 J

The change in temperature can be calculated as follows:

  ΔT=ΔPVnR=203 JnR

The value of change in internal energy will be equal to q4:

  q4=ΔH4=nCPΔT=n(52R)(203 JnR)=508 J

Similarly,

  ΔE4=nCVΔT=n(32R)(202.65 JnR)=304 J

The total value of work done, heat, change in internal energy and change in enthalpy for second path will be:

  q=q3+q4=(152+508) J=660 J

Similarly,

  w=w3+w4=(0+(204)) J=204 J

Also,

  ΔE=ΔE3+ΔE4=(152+304) J=456 J

And,

  ΔH=ΔH3+ΔH4=(253+508) J=761 J

Since, w and q are state functions thus, values for path 1 and path 2 are not same but sum of heat and work done is equal to change in internal energy in path 1 as well as path 2 this is in consistent with 1st law of thermodynamics.

The value of change in enthalpy and change in internal energy are state functions. The values are same for both paths.

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