Problem Set 4 Solutions

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Chemistry 360 Dr. Jean M. Standard

Problem Set 4 Solutions

1. Two moles of an ideal gas are compressed isothermally and reversibly at 298 K from 1 atm to 200 atm. Calculate q, w,

€

ΔU, and

€

ΔH.

For an isothermal reversible expansion of an ideal gas, the work is given by

€ w = − nRT ln V2 V₁ # $ % & ' ( .

The initial and final volumes are not given. However, for an isothermal process, from the ideal gas equation we have € P₁V₁ = P₂V₂, or € V₂ V₁ = P₁ P₂.

Substituting, the work can be calculated as

€ w = − nRT ln P1 P₂ # $ % & ' (

= − 2 mol

₍

₎

(

8.314 J mol−1K−1

)

₍

298 K

₎

ln 1 atm 200 atm # $ % & ' ( w = 26250 J .

For an ideal gas, the differential of the internal energy is given by

€

dU = CvdT and the differential of the

enthalpy is given by

€

dH = CpdT . Since the process is isothermal,

€ dT = 0, and so € dU = 0 and € dH = 0. Therefore, € ΔU = 0 and ΔH = 0. Finally, from the First Law of thermodynamics,

€ ΔU = q + w. Since € ΔU = 0, € q = − w = − 26250 J . Summary of results: q –26250 J w 26250 J € ΔU 0 J € ΔH 0 J

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2 2. A balloon filled with 0.505 mol of gas contracts reversibly from 1.0 L to 0.10 L at a constant temperature

of 5.0°C. It simultaneously loses 1270 J of heat. Calculate q, w,

€

ΔU, and

€

ΔH for the process.

For an isothermal reversible expansion of an ideal gas, the work is given by

€ w = − nRT ln V2 V₁ # $ % & ' ( .

Substituting, the work can be calculated as

€ w = − nRT ln V2 V₁ # $ % & ' ( = − 0.505 mol

₍

₎

(

8.314 J mol−1K−1

)

₍

278.15 K

₎

ln 0.10 L 1.0 L # $ % & ' ( w = 2690 J .

Even though the process described is isothermal, the overall internal energy change is not zero since the problem indicates that at the same time as the isothermal compression, heat is removed from the system. So, the First Law must be employed in order to determine

€

ΔU. The problem states that

€ q = –1270 J, so the First Law yields € ΔU = q + w = − 1270 J + 2690 J ΔU = 1420 J . Finally, to determine the enthalpy change

€

ΔH the definition of enthalpy may be used,

€

H = U + PV ΔH = ΔU + Δ PV

₍

₎

. In order to determine the change

€

Δ PV

₍

₎

= P₂V₂− P₁V₁, the volumes are given but the pressures are not. So, the ideal gas equation may be employed to determine the initial and final pressures,

€ P₁ = nRT V₁ = 0.505mol

(

)

(

0.08205L atm mol–1K–1

)

₍

278.15K

₎

1.0 L

(

)

P₁ = 11.525atm. and P₂ = nRT V₂ = 0.505mol

(

)

(

0.08205L atm mol–1K–1

)

₍

278.15K

₎

0.1L

(

)

P₂ = 115.25atm.

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3 2. Continued

Now the change

€ Δ PV

₍

₎

may be determined, € Δ PV

₍

₎

= P2V2− P1V1 = 115.25atm

₍

₎

₍

0.1L

₎

− 11.525atm

₍

₎

₍

1.0 L

₎

Δ PV

₍

₎

= 0.

It should not be a surprise that the factor

€

Δ PV

₍

₎

equals 0 since for an ideal gas another way to write this is

€

Δ PV

₍

₎

= Δ nRT

₍

₎

Δ PV

₍

₎

= nR ΔT . Since the temperature is constant,

€

ΔT = 0_{and as shown above,}

€

Δ PV

₍

₎

= nRΔT = 0. The enthalpy change is therefore given by € ΔH = ΔU + Δ PV

₍

₎

= ΔU ΔH = 1420 J. Summary of results: q –1270 J w 2690 J € ΔU 1420 J € ΔH 1420 J

3. The temperature dependence of the molar constant pressure heat capacity of a real gas may be represented by the function

€ C_p,m = α + β T + γ T2. where €

α

, € β , and €

γ_{are constants. For N}₂_{, these constants have the values}

€

α = 26.984 J K−1mol−1,

€

β = 5.910 ×10−3J K−2mol−1, and

€

γ = −3.377 ×10−7J K−3mol−1. Determine the amount of heat required to raise the temperature of 1 mol of N2 gas from 300 to 1000 K at constant pressure.

In this problem, we know that the heat at constant pressure is the enthalpy,

€

dq_p = dH . The exact differential of enthalpy is

dH = CpdT + ∂H ∂P # $ % & ' ( T dP .

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4 3. Continued

At constant pressure,

€

dP = 0, so the exact differential of enthalpy reduces to

€

dH = CpdT .

On a molar basis, this equation becomes

€ dH_m = Cp,mdT . Integrating, € dH_m H1,m H2,m

∫

= C_p,mdT T1 T2

∫

ΔHm =

(

α + β T + γ T2

)

dT T₁ T₂

∫

ΔHm = α T

(

2− T1

)

+ β₂

(

T22− T12

)

+ γ₃

(

T23− T13

)

.

Substituting the values of the parameters, we have

€ ΔHm = α T

(

2− T1

)

+ β₂

(

T22− T12

)

+ γ₃

(

T23− T13

)

ΔHm = 26.984 J mol

(

−1K−1

)

(

1000 K − 300 K

)

+ ₂1

(

5.910 ×10−3J mol−1K−2

)

( * ₎

₍

1000 K

₎

2− 300 K

₍

₎

2+ , - + 1₃

(

−3.377 × 10−7J mol−1K−3

)

(

₍

1000 K

₎

3− 300 K

₍

₎

3 ) * + , - = 18889 J/mol + 2689 J/mol − 110 J/mol

ΔHm = 21468 J/mol.

Thus, at constant pressure,

€

q_p,m = ΔHm = 21468 J/mol.

4. Estimate the final temperature of one mole of gas at 200.0 atm and 19.0°C as it is forced through a porous plug to a final pressure of 0.95 atm. The Joule-Thomson coefficient of the gas is 0.150 K/atm.

The Joule-Thomson coefficient

€ µJT is defined as € µ_JT = ∂ T ∂P # $ % & ' ( H .

Since the problem requests an estimate of the final temperature, we can approximate the derivative in the following way, µ_JT = ∂ T ∂P # $ % & ' ( H ≈ ΔT ΔP.

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5 4. Continued

We can solve the expression for the temperature difference

€ ΔT, € µ_JT ≈ ΔT ΔP or ΔT = µJTΔP .

Substituting the numerical values,

€

ΔT = µJT

(

P2− P1

)

= 0.150 K/atm

₍

₎

₍

0.95atm − 200.0 atm

₎

ΔT = − 29.86 K .

The final temperature then may be determined,

€ ΔT = T2− T1 = − 29.86 K or T₂ = T1 − 29.86 K T₂ = 292.16 K − 29.86 K T₂ = 262.29 K or – 10.9!C .

So for a pressure drop of nearly 200 atm, the temperature of this particular gas drops by nearly 30 degrees.

5. Determine the final temperature of 0.122 mol of an ideal monatomic gas that performs 75 J of work adiabatically if the initial temperature is 235°C.

For an adiabatic process, q=0, so from the First Law,

€

ΔU = q + w ΔU = w .

Now we are given the amount of work done and need to determine the final temperature. For an ideal gas, we can develop an expression for

€

ΔU in order to determine the temperature,

€

dU = CvdT (for an ideal gas) dU U₁ U₂

∫

= C_vdT T₁ T₂

∫

ΔU = Cv dT T₁ T₂

∫

ΔU = C_vΔT .

Note that this expression requires that the constant volume heat capacity is independent of temperature in order to pull it out of the integral.

So, for an adiabatic process involving an ideal gas, we have

€

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6 5. Continued

In order to evaluate this expression, we need the constant volume heat capacity. Any gas, monatomic, diatomic, or polyatomic, may behave ideally. Because these gases have different numbers of degrees of

freedom, they also have different heat capacities. It is indicated in this problem that the ideal gas is monatomic. For such a gas, we know that the constant volume heat capacity is

€ C_v = 3₂nR . Substituting, € ΔU = w = CvΔT = 3₂nR ΔT .

We can now solve this equation for the temperature difference,

€ ΔT = 2 w 3nR = 2 –75J

(

)

3 0.122 mol

₍

₎

₍

8.314 J/molK

₎

ΔT = − 49.29 K .

Note that the work is negative because the system performs work on the surroundings. The initial temperature is 235ºC or 508.15 K. Solving for the final temperature, we have

€ ΔT = T2− T1 = – 49.29 K or T₂= T1 − 49.29 K T₂= 508.15K − 49.29 K T₂= 458.86 K or 185.7!C .

6. A tank contains 20 L of compressed nitrogen at 10 atm and 25°C. Calculate the work when the gas is allowed to expand reversibly and adiabatically to 1 atm pressure. Assume that the gas behaves ideally. For an adiabatic process, we know that

€

q = 0. From the First Law,

€ ΔU = q + w. With € q = 0, we have € w = ΔU .

For an ideal gas, the differential of the internal energy is given by

€ dU = CvdT. Integrating, € dU U₁ U₂

∫

= C_vdT T₁ T₂

∫

. Assuming that €

Cv is independent of temperature, the integration yields

w = ΔU = Cv

(

T2−T1

)

.

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7 6. Continued

For a reversible adiabatic process, we derived in class that

€ C_vln T2 T₁ " # $ % & ' = − nR ln V2 V₁ " # $ % & ' .

Using properties of logarithms, we have

€ ln T2 T₁ " # $ % & ' C_v = ln V2 V₁ " # $ % & ' −nR .

Taking the exponential of both sides yields

€ T₂ T₁ " # $ % & ' C_v = V2 V₁ " # $ % & ' −nR , or € T₂ T₁ " # $ % & ' C_v = V1 V₂ " # $ % & ' nR .

For an ideal gas,

€

V = nRT

P , so the ratio of volumes on the right hand side of the equation can be rewritten to

give € T₂ T₁ " # $ % & ' C_v = T1P2 T₂P₁ " # $ % & ' nR .

Rearranging to get the temperatures on the left,

€ T₂ T₁ " # $ % & ' C_v T₂ T₁ " # $ % & ' nR = P2 P₁ " # $ % & ' nR T₂ T₁ " # $ % & ' C_v+nR = P2 P₁ " # $ % & ' nR T₂ T₁ = P₂ P₁ " # $ % & ' nR C_v+nR .

Solving for the final temperature,

€ T₂ = T1 P2 P₁ " # $ % & ' nR C_v+nR , T₂ = T1 P2 P₁ " # $ % & ' nR C_p .

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8 6. Continued

Note that nitrogen is not a monatomic ideal gas, so we need the actual heat capacity of nitrogen gas. From the CRC we have that

€

C_p,m = 29.125 J mol−1K−1. Therefore, the exponent is

€ nR C_p = nR nC_p,m = R C_p,m = 8.314 J mol −1_K−1 29.125J mol−1K−1 nR C_p = 0.28546.

The final temperature is

€ T₂ = T1 P2 P₁ " # $ % & ' 0.28546 = 298.15 K

₍

₎

1 atm 10 atm " # $ % & ' 0.28546 T₂ = 154.52 K .

Now, the work and internal energy change can be calculated using the relation

€

w = ΔU = Cv

(

T2−T1

)

= nC_v,m

₍

T₂−T₁

₎

. Since

€

C_p = Cv + nR , in terms of molar quantities, we have

€

C_p,m = Cv,m + R . We can solve for

€ C_v,m to get € C_v,m = Cp,m − R = 29.125J mol−1K−1 − 8.314 J mol−1K−1 C_v,m = 20.811J mol−1K−1.

The moles of nitrogen gas can be calculated from the initial state,

€ n = P1V1 RT₁ =

(

10 atm

)

(

20 L

)

0.08205 L atm mol−1K−1

(

)

₍

298.15 K

₎

n = 8.176 mol. Substituting, w = ΔU = nCv,m

(

T2− T1

)

= 8.176 mol

₍

₎

(

20.811J mol−1K−1

)

₍

154.52 K − 298.15K

₎

w = ΔU = − 24440 J .