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Chapter 17, Problem 43P

(a)

To determine

The specific heat of air at constant volume.

(a)

Expert Solution
Check Mark

Answer to Problem 43P

The specific heat of air at constant volume is 719.25 J/kg°C

Explanation of Solution

Given Info: Temperature of air is 300 K , Initial pressure is 2.00×105 Pa , Initial volume is 0.350 m3 , molar mass of air is 28.9 g/mol and specific heat at constant volume is 52R .

Formula for calculating the gas constant is,

R¯=RM

Here,

R¯ is the gas constant in J/kg°C

R is the universal gas constant

M is the molar mass of the gas

Substitute 8.314 J/molK for R and 28.9 g/mol for M to get R¯ ,

R¯=(8.314 J/molK)(28.9 g/mol)(1 kg1000 g)=287.7 J/kg°C

The specific heat at constant volume in J/kg can be given as,

CV=52R¯

Substitute 287.7 J/kg°C for R¯ in the above equation,

CV=52(287.7 J/kg°C)=719.25 J/kg°C

Thus, the specific heat at constant volume is 719.25 J/kg°C

Conclusion:

Therefore, the specific heat at constant volume is 719.25 J/kg°C

(b)

To determine

The mass of the air in the cylinder.

(b)

Expert Solution
Check Mark

Answer to Problem 43P

The mass of the air in the cylinder is 809.2g

Explanation of Solution

Given Info Temperature of air is 300 K , Initial pressure is 2.00×105 Pa , Initial volume is 0.350 m3 , molar mass of air is 28.9 g/mol and specific heat at constant volume is 52R .

According to the ideal gas equation,

PV=nRT

Here,

P is the pressure of the gas

V is the volume of the vessel

n is the number of moles

R is the gas constant

T is the temperature of the gas

Rearrange the above equation for n,

n=PVRT

Substitute 2.00×105 Pa for P , 0.350 m3 for V , 8.314 J/molK for R and 300 K for T in the above equation to get n

n=(2.00×105 Pa)(0.350 m3)(8.314 J/molK)(300 K)=28 mol

The number of moles of a gas is,

n=mM

Here,

m is the mass of the air

M is the molar mass of the air

Substitute 28 mol for n and 28.9 g/mol for M in the above equation,

(28 mol)=m(28.9 g/mol)m=809.2g

Thus, the mass of the air is 809.2 g

Conclusion:

Therefore, the mass of the air will be 809.2 g

(c)

To determine

The energy input required to raise the temperature to 700K

(c)

Expert Solution
Check Mark

Answer to Problem 43P

The energy input required to raise the temperature to 700K is 232.8kJ

Explanation of Solution

Given Info: Temperature of air is 300 K , Initial pressure is 2.00×105 Pa , Initial volume is 0.350 m3 , molar mass of air is 28.9 g/mol and specific heat at constant volume is 52R , final temperature of the air is 700K and piston is held fixed.

As the piston is held fixed, therefore, the process will be of constant volume.

The energy input for the given condition is given as,

Q=mCVΔT=mCV(TfTi)

Here,

Q is the energy input

m is the mass of the air

CV is the specific heat at constant volume

ΔT is the temperature difference

Tf is the final temperature of the air

Ti is the initial temperature of the air

Substitute 719.25 J/kgK for CV , 809.2 g for m , 700K for Tf and 300K for Ti to get Q in the above equation,

Q=[(809.2 g)(1kg1000g)](719.25 J/kgK)(700300)K=232806.84J=232.8kJ

Thus, the energy input required is 232.8kJ .

Conclusion:

Therefore, the energy input required will be 232.8kJ .

(d)

To determine

The energy input required to raise the temperature to 700K

(d)

Expert Solution
Check Mark

Answer to Problem 43P

The energy input required to raise the temperature to 700K is 325.93kJ

Explanation of Solution

Given Info: Temperature of air is 300 K , Initial pressure is 2.00×105 Pa , Initial volume is 0.350 m3 , molar mass of air is 28.9 g/mol and specific heat at constant volume is 52R , final temperature of the air is 700K and piston is free to move.

As the piston is free to move, therefore, the process will be of constant pressure.

The energy input for the given condition is given as,

Q=mCPΔT=mCP(TfTi) (1)

Here,

Q is the energy input

m is the mass of the air

CP is the specific heat at constant pressure

ΔT is the temperature difference

Tf is the final temperature of the air

Ti is the initial temperature of the air

The expression for gas constant for any ideal gas can be given as,

CPCV=R¯

Substitute 719.25 J/kgK for CV and 287.7 J/kgK for R¯ in the above equation,

CP(719.25 J/kgK)=(287.7 J/kgK)CP=1006.95J/kgK

Substitute 1006.95J/kgK for CP , 809.2 g for m , 700K for Tf and 300K for Ti to get Q in the equation (1),

Q=[(809.2 g)(1kg1000g)](1006.95J/kgK)(700300)K=325929.576J=325.93kJ

Thus, the energy input required is 325.93kJ .

Conclusion:

Therefore, the energy input required will be 325.93kJ .

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