EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 9780100454897
Author: Jewett
Publisher: YUZU
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Chapter 21, Problem 21.55AP

Model air as a diatomic ideal gas with M = 28.9 g/mol. A cylinder with a piston contains 1.20 kg of air at 25.0°C and 2.00 × 105 Pa. Energy is transferred by heat into the system as it is permitted to expand, with the pressure rising to 4.00 × 105 Pa. Throughout the expansion, the relationship between pressure and volume is given by P = CV1/2 where C is a constant. Find (a) the initial volume, (b) the final volume, (c) the final temperature, (d) the work done on the air, and (e) the energy transferred by heat.

(a)

Expert Solution
Check Mark
To determine

The initial volume.

Answer to Problem 21.55AP

The initial volume is 0.514m3 .

Explanation of Solution

Given info: Molar mass is 28.9g/mol , mass of gas is 1.20kg , temperature is 25.0°C , initial pressure is 2.00×105Pa and final pressure is 4.00×105Pa .

Write the expression for ideal gas equation.

P1V1=nRT1

Here,

P1 is initial pressure.

V1 is initial volume.

n is no. of molecule of gas.

R is universal gas constant.

T1 is initial temperature.

Reaarange above equation for V1 .

V1=nRT1P1 (2

Write the expression for number of moles of gas.

n=mgM (3)

Here,

mg is mass of gas.

M is molar mass.

Substitute 1.20kg for mg and 28.9g/mol for M in equation (3).

n=1.20kg28.9g/mol×1kg1000g=41.5mol

Thus, the number of moles of gas is 41.5mol .

Substitute 41.5mol for n , 8.314J/molK , 25.0°C for T1 and 2.00×105Pa in equation (2).

V1=(41.5mol)(8.314J/molK)(25.0+273K)2.00×105Pa=0.514(J×1Nm1JPa×1N/m21Pa)=0.514m3

Conclusion:

Therefore, the initial volume is 0.514m3 .

(b)

Expert Solution
Check Mark
To determine

The final volume.

Answer to Problem 21.55AP

The final volume is 2.06m3 .

Explanation of Solution

Given info: Molar mass is 28.9g/mol , mass of gas is 1.20kg , temperature is 25.0°C , initial pressure is 2.00×105Pa and final pressure is 4.00×105Pa .

Write the expression for the relationship between pressure and volume for adiabatic process for an ideal gas:

P1V1=P2V2

Rearrange equation (4) for V2 .

V2V1=P2P1

Square both side in above equation.

(V2V1)2=(P2P1)2V2=V1(P2P1)2 (4)

Substitute 0.514m3 for V1 , 2.00×105Pa for P1 and 4.00×105Pa in equation (4).

V2=(0.514m3)(4.00×105Pa2.00×105Pa)2=2.06m3

Conclusion:

Therefore, final volume is 2.06m3 .

(c)

Expert Solution
Check Mark
To determine

The final temperature.

Answer to Problem 21.55AP

The final temperature is 2.38×103K .

Explanation of Solution

Given info: Molar mass is 28.9g/mol , mass of gas is 1.20kg , temperature is 25.0°C , initial pressure is 2.00×105Pa and final pressure is 4.00×105Pa .

Write the expression for ideal gas equation.

P2V2=nRT2

Here,

P2 is final pressure.

V2 is final volume.

n is no. of molecule of gas.

R is universal gas constant.

T2 is final temperature.

Rearrange above equation for T2 .

T2=P2V2nR (5)

Substitute 4.00×105Pa for P2 , 2.06m3 for V2 as calculated in above part, 41.5mol for n as calculated in above part and 8.314J/molK for R in equation (5).

T2=(4.00×105Pa×1N/m21Pa)(2.06m3)(41.5mol)(8.314J/molk×1Nm1J)=2.38×103K

Conclusion:

Therefore, the final temperature is 2.38×103K .

(d)

Expert Solution
Check Mark
To determine

The workdone on the air.

Answer to Problem 21.55AP

The work done on the air is 480kJ .

Explanation of Solution

Given info: Molar mass is 28.9g/mol , mass of gas is 1.20kg , temperature is 25.0°C , initial pressure is 2.00×105Pa and final pressure is 4.00×105Pa .

Write the expression for work done.

W=V2V1PdV (6)

Here,

W is work done.

P is pressure.

V is volume.

Write the expression for relationship between pressure and volume:

P=CV12

Here,

C is constant.

Rewrite above expression for C .

C=PV12

Substitute CV1/2 for P in equation (6).

W=V2V1CV12dV=C|V32(32)|V2V1=2C3(V132V232)

Substitute PV12 for C in above expression.

W=23(P1V112)(V132V232) (7)

Substitute 2.00×105Pa for P1 , 0.514m3 for V1 and 2.06m3 for V2 in above equation.

W=2(2.00×105Pa×1N/m21Pa)3(0.514m3)12[(0.514m3)32(2.06m3)32]=480×103Nm×1kJ103Nm=480kJ

Conclusion:

Therefore, the work done on the air is 480kJ .

(e)

Expert Solution
Check Mark
To determine

The energy transferred by heat.

Answer to Problem 21.55AP

The energy transferred as heat is 2.28MJ .

Explanation of Solution

Given info: Molar mass is 28.9g/mol , mass of gas is 1.20kg , temperature is 25.0°C , initial pressure is 2.00×105Pa and final pressure is 4.00×105Pa .

The molar specific heat at constant pressure is,

cP=5R2

Write the expression for change in internal energy.

ΔEi=ncpΔT

Here,

ΔEi is change in internal energy.

n is no. of molecule of gas.

cp is molar specific heat at constant pressure.

ΔT is change in temperature.

Substitute 5R2 for cp and (T2T1) in above equation.

ΔEi=n5R2(T2T1) (8)

Here,

R is universal gas constant.

T2 is final temperature.

T1 is initial temperature.

Substitute 41.5mol for n as calculated in above part, 8.14J/molK for R , 2.38×103K for T2 and 298K for T1 in equation (8).

ΔEi=(41.5mol)(5×8.14J/molK)(2.38×103K298K)2=1.80×106J

Thus, the change in internal energy is 1.80×106J .

Write the expression for the energy transferred as heat.

Q=ΔEiW (9)

Here,

Q is energy transferred as heat.

ΔEi is change in internal energy.

W is work done.

Substitute 1.80×106J for ΔEi and 480kJ for W as calculated in above parts in equation (9).

Q=1.80×106J(480kJ×103J1kJ)=2.276×106J×1MJ106J=2.28MJ

Conclusion:

Therefore, the energy transferred as heat is 2.28MJ .

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Chapter 21 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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