WebAssign Printed Access Card for Serway/Vuille's College Physics, 11th Edition, Multi-Term
WebAssign Printed Access Card for Serway/Vuille's College Physics, 11th Edition, Multi-Term
11th Edition
ISBN: 9781337763486
Author: Raymond A. Serway, Chris Vuille
Publisher: Cengage Learning
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Chapter 12, Problem 72AP

(a)

To determine

The initial pressure in the vessel.

(a)

Expert Solution
Check Mark

Answer to Problem 72AP

the initial pressure in the vessel is 1.00×103Pa .

Explanation of Solution

Section1:

To determine: The constant volume occupied by the gas.

Answer: The volume of the gas is 0.524m3 .

Explanation:

Given Info:

The radius of the spherical vessel is 0.500m .

Formula to calculate the volume of the gas is,

V=43πr3

  • r is the radius of the vessel

Substitute 0.500m for r to find the volume.

VSun=43π(0.500m)3=0.524m3

Thus, volume of the gas is 0.524m3 .

Conclusion:

From section 1,

The volume of the gas is 0.524m3

The amount of hydrogen in the container is 14.4mol .

The amount of oxygen in the container is 7.2mol .

The initial temperature is 20°C

To find the initial pressure of the vessel, consider the components in the gas mixture in container as ideal gases. Hence, the total pressure the mixture exerts on the container will be the sum of pressure of the components of the mixture

The pressure exerted by the hydrogen molecule is,

PH2=nH2RTV (I)

  • nH2 is the amount of hydrogen molecules in moles
  • R is the universal gas constant
  • T is the absolute temperature
  • V is the volume of the container

The pressure exerted by the oxygen molecule is,

PO2=nO2RTV (II)

  • nO2 is the amount of oxygen molecule in moles

The total pressure exerted on the container is the sum of equation (I) and (II).

Therefore,

P=PH2+PO2=(nH2+nO2)RTV

Substitute 14.4mol for nH2 , 7.2mol for nO2 , 8.31J/molK for R, 20°C for T and 0.524m3 for V to find the initial pressure of the container,

P=(14.4mol+7.2mol)(8.31J/molK)((20+273)K)0.524m3=1.00×103Pa

Thus, the initial pressure in the vessel is 1.00×103Pa .

(b)

To determine

The initial internal energy of the gas.

(b)

Expert Solution
Check Mark

Answer to Problem 72AP

The initial internal energy of the gas is 1.31×105J

Explanation of Solution

Given Info:

The amount of hydrogen in the container is 14.4mol .

The amount of oxygen in the container is 7.2mol .

The molar specific heat of hydrogen at constant volume is 20.4J/mol.K .

The molar specific heat of oxygen at constant volume is 21.1J/molK .

The internal energy of the gas is the sum of the internal energy of the components of the gas mixture.

Formula to calculate the internal energy of the gas is,

U=UH2,i+UO2,i=(nO2Cv,o2+nH2Cv,H2)Ti

  • nO2 is the amount of oxygen in moles
  • Cv,o2 is the molar specific heat of oxygen in constant volume
  • nH2 is the amount of hydrogen in moles
  • Cv,H2 is the molar specific heat of hydrogen in constant volume

Substitute 14.4mol for nH2 , 20.4J/mol.K for Cv,H2 , 7.2mol nO2 and 21.1J/molK for Cv,o2 to find the initial internal energy of the gas,

Ui=|(14.4mol)(20.4J/molK)+(7.2mol)(21.1J/molS)|=1.31×105J

Thus, the initial internal energy of the gas is 1.31×105J

Conclusion:

The initial internal energy of the gas is 1.31×105J

(c)

To determine

The energy produced if the gas burns out to water vapor completely.

(c)

Expert Solution
Check Mark

Answer to Problem 72AP

The energy produced if the gas burns out to water vapor completely is 3.48×106J .

Explanation of Solution

Given Info:

The amount of hydrogen in the container is 14.4mol .

The amount of oxygen in the container is 7.2mol .

The initial temperature is 20°C

If the gas burns out to water vapor completely, instead of each one mole of hydrogen; one mole water will produce. In the container since the volume is constant, no other work done will be there. The water produced is equal to the amount of hydrogen.

Thus, the amount of water produced is 14.4mol .

The chemical energy required to produce one mole of water is 241.8kJ .

Formula to calculate the energy produced in combustion is,

ΔU=(241.8kJ/mol)n

  • n is the number of moles of water produced

Substitute 14.4mol for n to find the energy produced,

ΔU=(241.8kJ/mol)(14.4mol)=3.48×106J

Thus, the energy produced is 3.48×106J .

Conclusion:

The energy produced if the gas burns out to water vapor completely is 3.48×106J .

(d)

To determine

The temperature and pressure of the steam.

(d)

Expert Solution
Check Mark

Answer to Problem 72AP

The temperature and pressure of the water vapor is 9.28×103K and 2.12×106Pa .

Explanation of Solution

Section1:

To determine: The temperature of the steam

Answer: The final temperature of the steam is 9.28×103K

Explanation:

Given Info:

The molar heat capacity for water vapor is 27.0J/molK .

The initial internal energy of the gas is 1.31×105J .

The energy produced if the gas burns out to water vapor completely is 3.48×106J

For an ideal gas,

Formula to calculate the temperature of the steam is,

Tf=UfnwCv,w (I)

  • Uf is the final internal energy
  • nw is the amount of water in moles
  • Cv,w is the molar heat capacity of water

Since, after the combustion; the finial internal energy is,

Uf=Ui+ΔU

Thus, the equation (I) is given by,

Tf=Ui+ΔUnwCv,w

Substitute 1.31×105J for Ui , 3.48×106J for ΔU , 14.4mol for nw and 27.0J/molK for Cv,w to find the temperature of the steam,

T=(1.31×105J)(3.48×106J)(14.4mol)(27.0J/molK)=9.28×103K

Thus, the final temperature of the steam is 9.28×103K

Section2:

To determine: The pressure of the steam

Answer: The pressure of the steam is 2.12×106Pa

Explanation:

Given Info:

From section1,

The final temperature of the steam is 9.28×103K

For an ideal gas,

Formula to calculate the pressure of the steam is,

P=nwRTV

  • nw is the amount of water vapor in moles
  • R is the universal gas constant
  • T is the final temperature
  • V is the volume occupied by the gas

Substitute 14.4mol for nw , 8.31J/molK for R, 9.28×103K for T and 0.524m3 for V to find the pressure of the steam,

P=(14.4mol)(8.31J/molK)(9.28×103K)0.524m3=2.12×106Pa

Thus, the pressure of the steam is 2.12×106Pa

Conclusion:

The temperature and pressure of the water vapor is 9.28×103K and 2.12×106Pa .

(e)

To determine

The mass of steam and steam’s density.

(e)

Expert Solution
Check Mark

Answer to Problem 72AP

the mass of steam and steams density is 0.259kg and 0.494kg/m3 .

Explanation of Solution

Section1:

To determine: The mass of steam.

Answer: The mass of the steam is 0.259kg .

Explanation:

Given Info:

The mass of water is 18.0×103kg/mol

The amount of steam is 14.4mol

Formula to calculate the mass of the steam after the combustion is,

ms=nsMw

  • ns is the amount of steam in moles
  • Mw is the mass of water in moles

Substitute 14.4mol for ns and 18.0×103kg/mol for Mw to find the mass of steam,

ms=(14.4mol)(18.0×103kg/mol)=0.259kg

Thus, mass of the steam is 0.259kg .

Conclusion:

From section1,

Mass of the steam is 0.259kg .

The volume of the gas is 0.524m3 .

Formula to calculate the density of the steam is,

ρs=msV

  • ms is the mass of the steam
  • V is the volume of the gas

Substitute 0.259kg for ms , 0.524m3 for V to find the density of the steam,

ρs=0.259kg0.524m3=0.494kg/m3

Thus, the steam’s density is 0.494kg/m3 .

(f)

To determine

The initial exhaust velocity of the exhaust steam.

(f)

Expert Solution
Check Mark

Answer to Problem 72AP

The initial exhaust velocity of the exhaust steam is 2.93×103m/s .

Explanation of Solution

Given Info:

The Bernoulli’s equation is given by,

P2+12ρ2v22+ρsgh2=P1+12ρsv12+ρsgh1

Assume that the steam in the container is essentially at rest.

Thus,

v1=0 , P2=0 and h2=h1 .

Formula to calculate the exhaust velocity is,

v2=2P1ρs

  • P1 is the initial pressure of the gas
  • ρs is the density of the steam

Substitute 2.12×106Pa for P1 and 0.494kg/m3 for ρs to find the exhaust velocity,

v2=2(2.12×106Pa)0.494kg/m3=2.93×103m/s

Thus, the exhaust velocity is 2.93×103m/s .

Conclusion:

The initial exhaust velocity of the exhaust steam is 2.93×103m/s .

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Chapter 12 Solutions

WebAssign Printed Access Card for Serway/Vuille's College Physics, 11th Edition, Multi-Term

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