Please show all work. Legibility is a plus. Points awarded only if all answers a

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Please show all work. Legibility is a plus. Points awarded only if all answers are correct.

#1 A monatomic ideal gas is initially at a pressure of 120 kPa and volume of 5.5 L. The gas is then compressed adiabatically.

If Ti is the initial temperature of the gas, how much work must be done to raise the temperature of the gas to Tf = 2.8 Ti?

Give your answer in Joules to at least 3 significant digits. (Your answer should be positive.)

Answer:

#2 The P-V diagram shows a 4-step process where a monatomic ideal gas goes through a constant pressure compression (1 to 2), a constant volume pressure increase (2 to 3), a constant temperature expansion (3 to 4), and an adiabatic expansion (4 to 1).

In this process, V2 = 0.40 V1 and V4 = 0.85 V1.

What is the ratio of the change in thermal energy of the gas for the second process to the change in thermal energy for the fourth process?

In other words, what is (?E23 / ?E41) for this cycle?

Your answer should be unitless. Give your answer to at least three significant figures.

Hint: It helps to write everything in terms of T1, the temperature at the start, and ratios of volumes.

Warning: Signs matter.

Answer:

#3 An electrical power plant (a heat engine) has an efficiency of 35% and a cooling system that can handle a maximum heat exhaust of 4.7 MW (4.7 x 106 J/s).

What is the maximum output power that can be obtained from this power plant?

Give your answer in MW to at least 3 significant digits.             Answer:

#4 Consider a heat engine, diagrammed above.

The input energy (heat) is Qin = 850 J and the ouput exhaust energy (heat) is Qout = 350J.

If TH = 500 K, what is the largest possible value for TC?

Give your answer in Kelvin to at least three significant figures.

Answer:

Explanation / Answer

1)

W = (P2*V2 - P1*V1) / (k-1)

= nR(T2 - T1) / (k-1)

= nR(2.8*T1 - T1) / (k-1)

= 1.8*nRT1 / (k-1)

= 1.8*P1*V1 / (k-1)

= 1.8*(120*10^3) *(5.5*10^-3) / (1.67-1)

= 1773.134 J

2)

E23 = Cv(T3 - T2)

E41 = Cv(T1 - T4)

E23 / E41 = (T3 - T2) / (T1 - T4)

For process 1-2: V1 / T1 = V2 / T2

T2 = (V2 / V1)*T1

= 0.4*T1

For process 2-3:

P2 / T2 = P3 / T3

T3 / T2 = P3 / P2

T3 / T2 = P3 / P1

For process 3-4:

P3*V3 = P4*V4

P3/P4 = V4 / V3

= V4 / V2

= V4 / (0.4*V1)

= 0.85/ 0.4

= 2.125

P3 / P4 = 2.125

For process 4-1:

T4 / T1 = (V1 / V4)^(k-1)

= (1 / 0.85)^(1.67 - 1)

= 1.115

Also, P4 / P1 = (V1 / V4)^k

= (1 / 0.85)^1.67

= 1.3118

P3 / P1 = (P3 / P4)*(P4 / P1)

= 2.125*1.3118

= 2.7876

T3 / T2 = 2.7876

T3 / (0.4*T1) = 2.7876

T3 = 1.115*T1

E23 / E41 = (T3 - T2) / (T1 - T4)

= (1.115*T1 - 0.4*T1) / (T1 - 1.115*T1)

= -6.216

3)

Carnot efficiency = Power output / Heat input

= Powe routput / (Heat output + Power output)

0.35 = P / (P + 4.7)

P = 2.531 MW

4)

Carnot efficiency = 1 - Tc / Th = (Qin - Qout) / Qin

1 - Tc / 500 = (850 - 350) / 850

Tc = 205.882 K

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