Chapter 17

17.1. Model: For a gas, the thermal energy is the total kinetic energy of the moving molecules. That is, Eth = Kmicro. Solve:

The number of atoms is

N=

M 0.0020 kg = = 3.01 × 10 23 m 6.64 × 10 −27 kg

Because helium atoms have an atomic mass number A = 4, the mass of each helium atom is

m = 4 u = 4(1.661 × 10 −27 kg) = 6.64 × 10 −27 kg The average kinetic energy of each atom is 2 K avg = 12 mvavg =

1 2

(6.64 × 10

−27

kg)(700 m s) = 1.63 × 10−21 J 2

Thus the thermal energy of the gas is

Eth = K micro = NK avg = (3.01 × 10 23 )(1.63 × 10 −21 J ) = 490 J

17.2. Model: For a gas, the thermal energy is the total kinetic energy of the moving molecules. Solve:

Oxygen atoms have an atomic mass number A = 16, so the mass of each molecule is m = 32 u = 32(1.661 × 10−27 kg) = 5.32 × 10−26 kg

The number of molecules in the gas is

N=

M 0.0080 kg = 1.505 × 1023 = m 5.32 × 10 −26 kg

The thermal energy is

Eth = NK avg = N

(

1 2

)

2 ⇒ vavg = mvavg

2 Eth = Nm

2(1700 J ) = 650 m/s (1.505 × 10 23 )(5.32 × 10 −26 kg)

17.3. Model: The work done on a gas is the negative of the area under the pV curve. Visualize: Please refer to Figure Ex17.3. The gas is compressing, so we expect the work to be positive. Solve: The work done on the gas is

W = − ∫ p dV = −(area under the pV curve)

(

)

(

)

= − −(200 cm 3 )(200 kPa ) = (200 × 10 −6 m 3 ) 2.0 × 10 5 Pa = 40 J

Assess: The area under the curve is negative because the integration direction is to the left. Thus, the environment does positive work on the gas to compress it.

17.4. Model: The work done on a gas is the negative of the area under the pV curve. Visualize: Please refer to Figure Ex17.4. The gas is expanding, so we expect the work to be negative. Solve: The area under the pV curve is the area of the rectangle and triangle. We have

(200 × 10

−6

m 3 )(200 × 10 3 Pa ) +

1 2

(200 × 10

−6

m 3 )(200 × 10 3 Pa ) = 60 J

Thus, the work done on the gas is W = −60 J. Assess: The environment does negative work on the gas as it expands.

17.5. Visualize: Please refer to Figure Ex17.5. Solve:

The work done on gas in an isobaric process is

W = − p∆V = − p(Vf − Vi ) Substituting into this equation,

80 J = −(200 × 10 3 Pa )(V1 − 3V1 ) ⇒ Vi = 2.0 × 10 −4 m 3 = 200 cm 3 Assess: The work done to compress a gas is positive.

17.6. Model: Helium is an ideal gas that undergoes isobaric and isothermal processes. Solve:

(a) Since the pressure (p i = pf = p) is constant the work done is

Won gas = − p∆V = − p(Vf − Vi ) = −

nRTi (Vf − V i ) Vi

= − (0.10 mol)(8.31 J mol K )(573 K )

(1000 cm

3

− 2000 cm 3 )

2000 cm 3

= 238 J

(b) For compression at a constant temperature,

Won gas = − nRT ln(Vf Vi )  1000 × 10 −6 m 3  = −(0.10 mol)(8.31 J mol K )(573 K ) ln  = 330 J  2000 × 10 −6 m 3  (c) For the isobaric case,

p=

nRTi = 2.38 × 10 5 Pa Vi

For the isothermal case, pi = 2.38 × 10 5 Pa and the final pressure is

pf =

nRTf = 4.76 × 10 5 Pa Vf

17.7.

Solve:

Visualize:

Because W = − âˆŤ p dV and this is an isochoric process, W = 0 J. The final point is on a higher isotherm

than the initial point, so Tf > Ti. Heat energy is thus transferred into the gas (Q > 0) and the thermal energy of the gas increases (Eth f > Eth i) as the temperature increases.

17.8.

Solve:

Visualize:

Because this is an isobaric process W = − ∫ pdV = − p(Vf − Vi ) . Since Vf is smaller than Vi, W is positive.

That is, the gas is compressed. Since the final point is on a lower isotherm than the initial point, Tf < Ti. In other words, the thermal energy decreases. For this to happen, the heat energy transferred out of the gas must be larger than the work done.

17.9.

Visualize:

Solve: Because the process is isothermal, ∆Eth = Eth f – Eth i = 0 J. According to the first law of thermodynamics, ∆Eth = W + Q. This can only be satisfied if W = –Q. W is positive because the gas is compressing, hence Q is negative. That is, heat energy is removed from the gas.

17.10.

Visualize:

Solve: This is an adiabatic process of gas compression so no heat energy is transferred between the gas and the environment. That is, Q = 0 J. According to the first law of thermodynamics, the work done on a gas in an adiabatic process goes entirely to changing the thermal energy of the gas. The work W is positive because the gas is compressed.

17.11.

Visualize:

Solve:

This is a case of gas compression and therefore W = − âˆŤ pdV is a positive quantity. The final point is on a

lower isotherm than the initial point, so Tf < Ti. Heat energy is transferred out of the gas (Q < 0 J) and the thermal energy of the gas decreases as the temperature falls. That is, Eth f < Eth i. To bring about this process: (1) The locking pin is removed so the piston can slide up and down. (2) The masses on the top of the piston are not changed. This keeps the pressure constant. (3) The ice block is brought into contact with the bottom of the cylinder.

17.12.

Visualize:

Solve: For the isothermal process ∆T = 0 K. This means the first law of thermodynamics can only be satisfied if W = −Q. When the gas compresses, W > 0 J implying Q < 0 J. Heat energy is transferred out of the gas, but the temperature of the gas does not change. For the isochoric process, W ′ = 0 J because the volume does not change. Since the final point is on a lower isotherm, the final termperature is lower. That is, heat energy is transferred out of the gas (Q < 0) and hence the thermal energy of the gas decreases. To bring about this process: (1) Place the cylinder on the ice. The gas will begin to contract as heat energy is transferred to the ice. (2) Add masses on the top of the piston to increase the pressure and keep pV constant as the volume decreases. (3) At the desired volume and pressure, insert a locking pin into the piston to fix the volume. (4) Keep the ice in contact with the bottom of the cylinder until the original pressure is obtained in the gas.

17.13. Solve: The first law of thermodynamics is ∆Eth = W + Q ⇒ −200 J = 500 J + Q ⇒ Q = −700 J The negative sign means a transfer of energy from the system to the environment. Assess: Because W > 0 means a transfer of energy into the system, Q must be less than zero and larger in magnitude than W so that Eth f < Eth i.

17.14. Solve: This is an isobaric process. W > 0 because the gas is compressed. This transfers energy into the system. Also, 100 J of heat energy is transferred out of the gas. The first law of thermodynamics is

∆Eth = W + Q = − p∆V + Q = –(4.0 × 105 Pa)(200 – 600) × 10−6 m3 – 100 J = 60 J Thermal energy increases by 60 J.

17.15. Model: The removal of heat from the ice reduces its thermal energy and its temperature. Solve:

The heat needed to change an object’s temperature is Q = Mc∆T. The mass of the ice cube is M = ρiceV = (920 kg/m3)(0.06 × 0.06 × 0.06) m3 = 0.199 kg

The specific heat of ice from Table 17.2 is cice = 2090 J/kg K, so Q = (0.199 kg)(2090 J/kg K)(243 K – 273 K) = –12,500 J Thus, the energy removed from the ice block is 12,500 J. Assess: The negative sign with Q means loss of energy.

17.16. Model: The spinning paddle wheel does work and changes the water’s thermal energy and its temperature. Solve: (a) The temperature change is ∆T = Tf – Ti = 25°C − 21°C = 4 K. The mass of the water is M = (200 × 10−6 m3)(1000 kg/m3) = 0.20 kg The work done is W = ∆Eth = Mcwater∆T = (0.20 kg)(4190 J/kg K)(4 K) = 3350 J (b) Q = 0. No energy is transferred between the system and the environment because of a difference in temperature.

17.17. Model: Heating the mercury at its boiling point changes its thermal energy without a change in temperature. Solve: The mass of the mercury is M = 20 g = 2.0 × 10−2 kg, the specific heat cmercury = 140 J/kg K, the boiling point Tb = 357°C, and the heat of vaporization LV = 2.96 × 105 J/kg. The heat required for the mercury to change to the vapor phase is the sum of two steps. The first step is Q1 = Mcmercury∆T = (2.0 × 10−2 kg)(140 J/kg K)(357°C − 20°C) = 944 J The second step is Q2 = MLV = (2.0 × 10−2 kg)(2.96 × 105 J/kg) = 5920 J The total heat needed is 6864 J.

17.18. Model: Heating the mercury changes its thermal energy and its temperature. Solve:

(a) The heat needed to change the mercury’s temperature is Q = McHg∆T ⇒ ∆T =

Q 100 J = = 35.7 K = 35.7°C McHg (0.020 kg)(140 J kg K )

(b) The amount of heat required to raise the temperature of the same amount of water by the same number of degrees is Q = Mcwater∆T = (0.020 kg)(4190 J/kg K)(35.7 K) = 2990 J Assess: Q is directly proportional to cwater and the specific heat for water is much higher than the specific heat for mercury. This explains why Qwater > Qmercury.

17.19. Model: Changing ethyl alcohol at 20°C to solid ethyl alcohol at its melting point requires two steps: lowering its temperature from 20°C to −114°C, then changing the ethyl alcohol to its solid phase at −114°C. Solve: The change in temperature is −114°C − 20°C = −134°C = −134 K. The mass is M = ρV = (789 kg / m 3 )(200 × 10 −6 m 3 ) = 0.1578 kg The heat needed for the two steps is Q1 = Mcalcohol∆T = (0.1578 kg)(2400 J/kg K)(−134 K)= −5.075 × 104 J Q2 = −MLf = − (0.1578 kg)(1.09 × 105 J/kg) = −1.720 × 104 J The total heat required is Q = Q1 + Q2 = −6.79 × 104 J Thus, the minimum amount of energy that must be removed is 6.79 × 104 J. Assess: The negative sign with Q indicates that 6.79 × 104 J will be removed from the system.

17.20. Model: Changing solid lead at 20°C to liquid lead at its melting point (Tm = 328°C) requires two steps: raising the temperature to Tm and then melting the solid at Tm to a liquid at Tm. Solve: The equation for the total heat is Q = Q1 + Q2 ⇒ 1000 J = Mclead(Tf – Ti) + MLf

⇒ 1000 J = M(128 J/kg K)(328 – 20) K + M(0.25 × 105 J/kg) ⇒ M = The maximum mass of lead you can melt with 1000 J of heat is 15.5 g.

1000 J

(64,424 J kg)

= 15.5 g

17.21. Model: We have a thermal interaction between the copper pellets and the water. Solve:

The conservation of energy equation Qc + Ww = 0 is

Mc cc (Tf − 300°C) + Mw cw (Tf − 20°C) = 0 J Solving this equation for the final temperature Tf gives M c (300°C) + Mw cw (20°C) Tf = c c M c cc + M w c w

=

(0.030 kg)(385 J / kg K) (300°C) + (0.10 kg)(4190 J / kg K) (20°C) = 27.5°C (0.030 kg)(385 J / kg K) + (0.10 kg)(4190 J / kg K)

The final temperature of the water and the copper is 27.5°C.

17.22. Model: We have a thermal interaction between the copper block and water. Solve:

The conservation of energy equation Qcopper + Qwater = 0 J is

Mcopperccopper (Tf – Ti copper) + Mwatercwater(Tf – Ti water) = 0 J Both the copper and the water reach the common final temperature Tf = 25.5°C. Thus Mcopper(385 J/kg K)(25.5°C – 300°C) + (1.0 × 10−3 m3)(1000 kg/m3)(4190 J/kg K)(25.5°C – 20°C) = 0 J

⇒ M copper = 0.218 kg

17.23. Model: We have a thermal interaction between the thermometer and the water. Solve:

The conservation of energy equation Qthermo + Qwater = 0 J is

Mthermocthermo(Tf – Ti thermo) + Mwatercwater(Tf – Ti water) = 0 J The thermometer slightly cools the water until both have the same final temperature Tf = 71.2°C. Thus

(0.050 kg)(750 J / kg K)(71.2°C − 20.0°C) + (200 × 10 −6 m 3 )(1000 kg / m 3 )( 4190 J / kg K)(71.2°C − Ti water ) = 1920 J + 838 (J / K)(71.2°C − Ti water ) = 0 J ⇒ Ti water = 73.5°C Assess: The thermometer reads 71.2°C for a real temperature of 73.5°C. This is reasonable.

17.24. Model: We have a thermal interaction between the aluminum pan and the water.

The conservation of energy equation QAl + Qwater = 0 J is MAl cAl(Tf – Ti Al) + Mwater cwater(Tf – Ti water) The pan and water reach a common final temperature Tf = 24.0°C Solve:

(0.750 kg)(900 J / kg K)(24.0°C − Ti Al ) + (10 × 10 −3 m 3 )(1000 kg / m 3 )(4190 J / kg K)(24.0°C − 20.0°C ) = (675.0 J / K)(24.0°C − Ti Al ) + 167,600 J = 0 J ⇒ Ti Al = 272°C = [(272) (9/5) + 32]°F = 522°F

17.25. Model: We have a thermal interaction between the metal sphere and the mercury. Solve:

The conservation of energy equation Qmetal + QHg = 0 J is

Mmetalcmetal(Tf – Ti metal) + MHgcHg(Tf – Ti Hg) = 0 J The metal and mercury reach a common final temperature Tf = 99.0°C. Thus (0.500 kg)cmetal(99°C – 300°C) + (300 × 10−6 m3)(13,600 kg/m3)(140 J/kg K)(99°C – 20°C) = 0 J We find that cmetal = 449 J kg K . The metal is iron.

17.26. Model: Use the models of isochoric and isobaric heating. Note that the change in temperature on the Kelvin scale is the same as the change in temperature on the Celsius scale. Solve: (a) The atomic mass number of argon is 40. That is, Mmol = 40 g/mol. The number of moles of argon gas in the container is

n=

M 1.0 g = = 0.025 mol Mmol 40 g mol

The amount of heat is Q = nCV ∆T = (0.025 mol)(12.5 J/mol K)(100°C) = 31.25 J (b) For the isobaric process Q = nCP ∆T becomes 31.25 J = (0.025 mol)(20.8 J/mol K)∆T ⇒ ∆T = 60°C

17.27. Model: The heating processes are isobaric and isochoric. O2 is a diatomic ideal gas. Solve:

(a) The number of moles of oxygen is

n=

M 1.0 g = = 0.03125 mol Mmol 32 g mol

For the isobaric process, Q = nCP ∆T = (0.03125 mol)(29.2 J/mol K)(100°C) = 91.2 J (b) For the isochoric process, Q = nCV ∆T = 91.2 J = (0.03125 mol)(20.9 J/mol K)∆T ⇒ ∆T = 140°C

17.28. Model: The heating is an isochoric process. Solve:

The number of moles of helium is

n=

M 2.0 g = = 0.50 mol Mmol 4 g mol

For the isochoric processes,

QHe = nCV ∆T = (0.50 mol)(12.5 J mol K )∆T

  M QO2 = nCV ∆T =   (20.9 J mol K )∆T  32 g mol 

Because QHe = QO2 ,

  M  (20.9 J mol K ) ⇒ M = 9.57 g  32 g mol 

(0.50 mol)(12.5 J mol K) = 

17.29. Model: The O2 gas has γ = 1.40 and is an ideal gas. Solve:

(a) For an adiabatic process, pV γ remains a constant. That is, γ

V   V  pi Viγ = pf Vfγ ⇒ pf = pi  i  = (3.0 atm) i   Vf   2Vi 

1.40

1 = (3.0 atm)   2

1.40

= 1.14 atm

(b) Using the ideal-gas law, the final temperature of the gas is calculated as follows:

p V pi Vi pV  1.14 atm   2Vi  = 321.5 K = 48.5°C = f f ⇒ Tf = Ti f f = ( 423 K )  3.0 atm   Vi  pi Vi Ti Tf

17.30. Model: We assume the gas is an ideal gas and γ = 1.40 for a diatomic gas. Solve:

Using the ideal-gas law,

Vi =

nRTi (0.10 mol)(8.31 J mol K )( 423 K ) = = 1.157 × 10 −3 m 3 pi 3 × 1.013 × 10 5 Pa

(

)

For an adiabatic process,

pi Viγ = pf Vfγ

p ⇒ Vf = Vi  i   pf 

1γ

 p  = (1.157 × 10 −3 m 3 ) i   0.5 pi 

1 1.40

= 1.90 × 10 −3 m 3

To find the final temperature, we use the ideal-gas law once again as follows:

Tf = Ti

 0.5 pi   1.90 × 10 −3 m 3  pf Vf = ( 423 K ) = 346.9 K = 73.9°C  −3 3 pi Vi  pi   1.157 × 10 m 

17.31. Model: γ is 1.40 for a diatomic gas and 1.67 for a monoatomic gas. Solve:

(a) We will assume that air is a diatomic gas. For an adiabatic process,

Tf Vfγ −1 = Ti Viγ −1 Thus 1

1

 Vi   Tf  γ −1  1123 K  1.40 −1 = = 26.4   =   303 K   Vf   Ti  (b) For argon, a monatomic gas, 1

 Vi   1123 K  1.67−1 = 7.07   = 303 K   Vf 

17.32. Model: Changing steam to ice requires four steps: removing heat to convert steam into water at 100°C, removing heat to lower the water temperature from 100°C to 0°C, converting water at 0°C to ice at 0°C, and lowering the temperature of ice to −20°C. Solve: Number of moles of steam is

n=

(

)

2 × 1.013 × 10 5 Pa (1530 × 10 −6 m 3 ) pV = = 0.10 mol RT (8.31 J mol K)(373 K)

The mass of steam is

M = nMmol = (0.10 mol)(18 g mol) = 1.8 g = 0.0018 kg The heat needed for each step is

(

)

(

)

Q1 = − MLV = −(0.0018 kg) 22.6 × 10 5 J kg = −4068 J Q2 = Mcwater ∆Twater = (0.0018 kg)( 4190 J kg K )(0°C − 100°C) = −754.2 J Q3 = − MLf = −(0.0018 kg) 3.33 × 10 5 J kg = −599.4 J Q4 = Mcice ∆Tice = (0.0018 kg)(2090 J kg K )( −20°C − 0°C) = −75.24 J The total heat required in this process is

Q = Q1 + Q2 + Q3 + Q4 = −5497 J Assess: Approximately 75% of the heat is removed from steam at 100°C to make water at 100°C. This is consistent with our experience that it takes much longer for a pan of water to boil away than it does to reach boiling.

17.33. Solve: The area of the garden pond is A = π (2.5 m )2 = 19.635 m 2 and its volume is V = A(0.30 m ) = 5.891 m 3 . The mass of water in the pond is

M = ρV = (1000 kg m 3 )(19.635 m 3 ) = 5891 kg The water absorbs all the solar power which is

(400 W m )(19.635 m ) = 7854 W 2

2

This power is used to raise the temperature of the water. That is,

Q = (7854 W )∆t = Mcwater ∆T = (5891 kg)( 4190 J kg K )(10 K ) ⇒ ∆t = 31,425 s = 8.73 hr

17.34. Model: The potential energy of the bowling ball is transferred into the thermal energy of the mixture. We assume the starting temperature of the bowling ball to be 0°C. Solve: The potential energy of the bowling ball is

U g = M ball gh = (11 kg)(9.8 m s 2 )h = (107.8 kg m s 2 )h This energy is transferred into the mixture of ice and water and melts 5 g of ice. That is,

(107.8 kg m s2 )h = ∆Eth = Mw Lf ⇒ h =

(0.005 kg)(3.33 × 10 5

(107.8 kg m s ) 2

J kg

) = 15.45 m

17.35. Model: Heating the water and the kettle raises the temperature of the water to the boiling point and raises the temperature of the kettle to 100°C. Solve: The amount of heat energy from the electric stove’s output in 3 minutes is

Q = (2000 J s)(3 × 60 s) = 3.6 × 10 5 J This heat energy heats the kettle and brings the water to a boil. Thus,

Q = Mwater cwater ∆T + M kettle ckettle ∆T Substituting the given values into this equation,

3.6 × 10 5 J = Mwater ( 4190 J kg K )(100°C − 20°C) + (0.750 kg)( 449 J kg K )(100°C − 20°C)

⇒ Mwater = 0.994 kg The volume of water in the kettle is

V=

Mwater 0.994 kg = = 0.994 × 10 −3 m 3 = 994 cm 3 ρ water 1000 kg m 3

Assess: 1 L = 103 cm3, so V ≈ 1 L. This is a reasonable volume of water.

17.36. Model: Each car’s kinetic energy is transformed into thermal energy. Solve:

For each car,

K = 12 Mv 2 = ∆Eth = Mccar ∆T ⇒ ∆T =

v2 2ccar

Assume ccar = ciron. The speed of the car is

(22.22 m s) = 0.55°C 80 × 1000 m = 22.22 m s ⇒ ∆T = 2( 449 J kg K ) 3600 s 2

v = 80 km hr =

17.37. Model: There are three interacting systems: aluminum, copper, and ethyl alcohol.

Solve: The aluminum, copper, and alcohol form a closed system, so Q = QAl + QCu + Qeth = 0 J. The mass of the alcohol is

Meth = ρV = (790 kg m 3 )(50 × 10 −6 m 3 ) = 0.0395 kg Expressed in terms of specific heats and using the fact that ∆T = Tf – Ti, the Q = 0 J condition is

MAl cAl ∆TAl + MCu cCu ∆TCu + Meth ceth ∆Teth = 0 J Substituting into this expression,

(0.010 kg)(900 J kg K)(298 K − 473 K) + (0.020 kg)(385 J kg K)(298 K − T ) + (0.0395 kg)(2400 J kg K )(298 K − 288 K ) = −1575 J + (7.7 J K )(298 − T ) + 948 J = 0 J ⇒ T = 216.6 K = −56.4°C

17.38. Model: There are two interacting systems: aluminum and ice. The system comes to thermal equilibrium in four steps: (1) the ice temperature increases from −10°C to 0°C, (2) the ice becomes water at 0°C, (3) the water temperature increases from 0°C to 20°C, and (4) the cup temperature decreases from 70°C to 20°C. Solve: The aluminum and ice form a closed system, so Q = Q1 + Q2 + Q3 + Q4 = 0 J. These quantities are

Q1 = Mice cice ∆T = (0.100 kg)(2090 J kg K )(10 K ) = 2090 J

(

)

Q2 = Mice Lf = (0.100 kg) 3.33 × 10 5 J kg = 33,300 J Q3 = Mice cwater ∆T = (0.100 kg)( 4190 J kg K )(20 K ) = 8380 J Q4 = MAl cAl ∆T = MAl (900 J kg K )( −50 K ) = −( 45,000 J kg) M Al The Q = 0 J equation now becomes 43,770 J – (45,000 J/kg)MAl = 0 J The solution to this is MAl = 0.973 kg.

17.39. Model: There are three interacting systems: metal, aluminum, and water.

Solve: The metal, aluminum container, and water form a closed system, so Qm + QAl + Qw = 0 J, where Qm is the heat transferred to the metal sample. This equation can be written: Mmcm∆Tm + MAlcAl∆TAl + Mwcw∆T = 0 J Substituting in the given values,

(0.512 kg)cm (351 K − 288 K) + (0.100 kg)(900 J kg K)(351 K − 371 K) + (0.325 kg)( 4190 J kg K )(351 K − 371 K ) = 0 J ⇒ cm = 900 J kg K From Table 17.2, we see that this is the specific heat of aluminum.

17.40. Solve: For a monatomic gas, the molar specific heat at constant volume is CV = 12.5 J mol K . From Equation 17.22,

12.5 J mol K = The gas is therefore neon.

Mmol 625 J kg K ⇒ Mmol = 20 g mol 1000 g kg

17.41. Model: Heating the water raises its thermal energy and its temperature. Solve: A 5.0 kW heater has power P = 5000 W. That is, it supplies heat energy at the rate 5000 J/s. The heat supplied in time ∆t is Q = 5000∆t J. The temperature increase is ∆TC = (5/9)∆TF = (5/9)(75°) = 41.67°C. Thus

Q = 5000 ∆t J = Mcw ∆T = (150 kg)(4190 J / kg K) (41.67°C) ⇒ ∆t = 5283 s = 87.3 min Assess: A time of ≈1.5 hours to heat 40 gallons of water is reasonable.

17.42. Model: Heating the material increases its thermal energy. Visualize: Please refer to Figure P17.42. Heat raises the temperature of the substance from –40°C to –20°C, at which temperature a solid to liquid phase change occurs. From –20°C, heat raises the liquid’s temperature up to 40°C. Boiling occurs at 40°C where all of the liquid is converted into the vapor phase. Solve: (a) In the solid phase,

∆Q = Mc∆T ⇒ c =

 ∆Q  1  20 kJ   1  = = 2000 J kg K  ∆T  M  20 K   0.50 kg 

(b) In the liquid phase,

1  ∆Q   1   80 kJ  = = 2667 J kg K  M  ∆T   0.50 kg   60 K  (c) The melting point Tm = −20°C and the boiling point Tb = +40°C . (d) The heat of fusion is c=

Lf =

Q 20,000 J = = 4.0 × 10 4 J kg M 0.50 kg

Lv =

Q 60,000 J = = 1.2 × 10 5 J kg M 0.50 kg

The heat of vaporization is

17.43. Model: Heating the material increases its thermal energy. Visualize: Please refer to Figure P17.43. The material melts at 300°C and undergoes a solid-liquid phase change. The material’s temperature increases from 300°C to 1500°C. Boiling occurs at 1500°C and the material undergoes a liquid-gas phase change. Solve: (a) In the liquid phase, the specific heat of the liquid can be obtained as follows:

∆Q = Mc∆T ⇒ c =

  20 kJ  1 1 ∆Q  = = 83.3 J kg K  M ∆T  0.200 kg   1200 K 

(b) The latent heat of vaporization is

Lv =

Q 40 kJ = 2.0 × 10 5 J kg = M (0.200 kg)

17.44. Model: The liquefaction of the nitrogen occurs in two steps: lowering nitrogen’s temperature from 20°C

to −196°C, and then liquefying it at −196°C. Assume the cooling occurs at a constant pressure of 1 atm. Solve: The mass of 1.0 L of liquid nitrogen is M = ρV = 810 kg m 3 10 −3 m 3 = 0.810 kg . This mass corresponds to

(

n=

)(

)

M 810 g = = 28.9 mols Mmol 28 g mol

At constant atmospheric pressure, the heat to be removed from 28.93 mols of nitrogen is

Q = MLv + nCP ∆T

(

)

= −(0.810 kg) 1.99 × 10 5 J kg + (28.9 mols)(29.1 J mol K )(77 K − 293 K ) = −3.43 × 10 5 J

17.45. Model: There are two interacting systems: coffee (i.e., water) and ice. Changing the coffee temperature from 90°C to 60°C requires four steps: (1) raise the temperature of ice from −20°C to 0°C, (2) change ice at 0°C to water at 0°C, (c) raise the water temperature from 0°C to 60°C, and (4) lower the coffee temperature from 90°C to 60°C. Solve: For the closed coffee-ice system,

Q = Qice + Qcoffee = (Q1 + Q2 + Q3 ) + (Q4 ) = 0 J Q1 = Mice cice ∆T = Mice (2090 J kg K )(20 K ) = Mice ( 41,800 J kg) Q2 = Mice Lf = Mice (330,000 J kg) Q3 = Mice cwater ∆T = Mice ( 4190 J kg K )(60 K ) = Mice (251,400 J kg)

Q4 = Mcoffee ccoffee ∆T = (300 × 10 −6 m 3 )(1000 kg m 3 )( 4190 J kg K )( −30 K ) = −37, 000 J The Q = 0 J equation thus becomes

Mice ( 41, 800 + 330, 000 + 251, 400) J kg − 37, 710 J = 0 J ⇒ Mice = 0.0605 kg = 60.5 g Visualize:

60.5 g is the mass of approximately 1 ice cube.

17.46. Model: There are two interacting systems: the nuclear reactor and the water. The heat generated by the nuclear reactor is used to raise the water temperature. Solve: For the closed reactor-water system, energy conservation per second requires Q = Qreactor + Qwater = 0 J The heat from the reactor in ∆t = 1 s is Qreactor = −2000 MJ = −2.0 × 10 9 J and the heat absorbed by the water is

Qwater = mwater cwater ∆T = mwater ( 4190 J kg K )(12 K )

⇒ −2.0 × 10 J + mwater ( 4190 J kg K )(12 K ) = 0 J ⇒ mwater = 3.98 × 10 4 kg 9

Each second, 3.98 × 104 kg of water is needed to remove heat from the nuclear reactor. Thus, the water flow per minute is kg 60 s 1m 3 1L 3.98 × 10 4 × × × −3 3 = 2.39 × 106 L/min s min 1000 kg 10 m

17.47. Model: We have three interacting systems: the aluminum, the air, and the firecracker. The energy released by the firecracker raises the temperature of the aluminum and the air. We will assume that air is basically N2. Solve: For the closed firecracker + air + aluminum system, energy conservation requires that Q = Qfirecracker + QAl + Qair = 0 J QAl = mAlcAl∆T = (2.0 kg)(900 J/kg K)(3 K) = 5400 J pV  Qair = nCV ∆T =  C ∆T  RT  V

=

(1.01 × 10

5

)

Pa (20 × 10 −3 m 3 )

(8.31 J / mol K)(298 K) = 51 J

(20.8 J / mol K)(3 K)

Thus, Qfirecracker = −QAl − Qair = −5450 J That is, 5450 J of energy are released on explosion of the firecracker. Assess: The negative sign with Qfirecracker means that the firecracker has lost energy.

17.48. Model: We have two interacting systems: the water and the gas. For the closed system comprised of water and gas to come to equilibrium, heat is transferred from one interacting system to the other. Solve: Energy conservation requires that Qair + Qwater = 0 J ⇒ ngasCV (Tf – Ti gas) + mwaterc(Tf – Ti water) = 0 J Using the ideal-gas law,

Ti gas =

pgas Vgas ngas R

(10 × 1.013 × 10 Pa)(4000 × 10 5

=

−6

(0.40 mol)(8.31 J mol K)

m3 )

= 1219 K

The energy conservation equation with Ti water = 293 K becomes

(0.40 mol)(12.5 J mol K)(T − 1219 K) + (20 × 10 −3 kg)(4190 J kg K)(T − 293 K) = 0 J ⇒ Tf = 345 K We can now use the ideal-gas equation to find the final gas pressure. pi Vi pV T 345 K  = f f ⇒ pf = pi f =  (10 atm) = 2.83 atm Ti Tf Ti  1219 K 

17.49. Model: For a gas, the thermal energy is the total kinetic energy of the moving molecules. That is, Eth = Kmicro. Also, the work W done on an expanding gas is negative. Solve:

( )

(a) The thermal energy of N molecules is Eth = NKavg, where K avg = 12 m vavg

2

is the average kinetic

energy per molecule. The mass of a hydrogen molecule is

m = 2 u = 2 × (1.661 × 10 −27 kg) = 3.32 × 10 −27 kg

The number of molecules in a 1 g = 0.001 kg sample is M 0.001 kg N= = = 3.01 × 10 23 m 3.32 × 10 −27 kg The average kinetic energy per molecule is

( )

K avg = 12 m vavg

2

=

1 2

(3.32 × 10

−27

kg)(700 m s) = 8.13 × 10 −22 J 2

Thus, the thermal energy in the 1-gram sample of the gas is

Eth = NK avg = (3.01 × 10 23 )(8.13 × 10 −22 J ) = 245 J

(b) The first law of thermodynamics tells us the change of thermal energy when work is done and heat is added: ∆Eth = W + Q = −300 J + 500 J = 200 J Here W is negative because energy is transferred from the system to the environment. The work and heat raise the thermal energy of the gas by 200 J to Eth = 445 J. Now the average kinetic energy is

( )

K avg = Eth N = 1.487 × 10 −21 J = 12 m vavg

2

Solving for the new average speed gives

vavg =

2 K avg m

=

2(1.478 × 10 −21 J ) 3.32 × 10 −27 kg

= 944 m s

17.50. Model: These are isothermal and isobaric ideal-gas processes. Solve:

(a) The work done at constant temperature is Vf Vf nRT W = − ∫ pdV = − ∫ dV = − nRT (ln Vf − ln Vi ) = − nRT ln(Vf Vi ) Vi Vi V = −(2.0 mol)(8.31 J mol K )(303 K ) ln( 13 ) = 5530 J

(b) The work done at constant pressure is

W = − ∫ p dV = − p(Vf − Vi ) = − p Vf

Vi

=

 Vi  2 − Vi = pVi 3  3

2 2 nRT = (2.0 mol)(8.31 J mol K )(303 K ) = 3360 J 3 3

(c) For an isothermal process in which Vf = 13 Vi , the pressure changes to pf = 3 pi = 4.5 atm.

17.51. Model: This is an isothermal process. The work done is positive for a compression. Solve:

For an isothermal process,

W = − nRT ln(Vf Vi ) For the first process,

W = 500 J = − nRT ln( 12 ) ⇒ nRT = 721.35 J For the second process,

W = − nRT ln( 101 ) ⇒ W = −(721.35 J ) ln( 101 ) = 1660 J

17.52.

Visualize:

Solve:

(a) The gas exerts a force on the piston of magnitude

[

Fgas on piston = pgas A = (3 atm × 101,300 Pa atm) π (0.080 m )

2

] = 6110 N

This force is directed toward the right. (b) The piston is in static equilibrium, so the environment must exert a force on the piston of equal magnitude Fenviron on piston = 6110 N but in the opposite direction, toward the left. (c) The work done by the environment is r r r Wenviron = Fenviron on piston ⋅ ∆r = − Fenviron on piston ∆x = −(6110 N )(0.10 m ) = −611 J The work is negative because the force and the displacement are in opposite directions. (d) The work done by the gas is r r Wgas = Fgas on piston ⋅ ∆r = + Fgas on piston ∆x = (6110 N )(0.10 m ) = 611 J This work is positive because the force and the displacement are in the same direction. (e) The first law of thermodynamics is W + Q = ∆Eth where W is Wenviron. So here W = −611 J and we find

Q = ∆Eth − W = (196 J ) − ( −611 J ) = 807 J Thus, 807 J of heat is added to the gas.

17.53. Model: This is an isobaric process. Visualize:

Solve: (a) The initial conditions are p1 = 10 atm = 1.013 × 106 Pa, T1 = 50°C = 323 K, V1 = πr2L1 = π(0.050 m)2 (0.20 m) = 1.57 × 10−3 m3. The gas is heated at a constant pressure, so heat and temperature change are related by Q = nCP∆T. From the ideal gas law, the number of moles of gas is

n=

6 −3 3 p1V1 (1.013 × 10 Pa )(1.57 × 10 m ) = 0.593 mol = RT1 (8.31 J mol K)(323 K)

The temperature change due to the addition of Q = 2500 J of heat is thus Q 2500 J ∆T = = = 203 K nCP (0.593 mol)(20.8 J mol K ) The final temperature is T2 = T1 + ∆T = 526 K = 253°C. (b) Noting that the volume of a cylinder is V = πr2L and that r doesn’t change, the ideal gas relationship for an isobaric process is V2 V1 L L T 526 K = ⇒ 2 = 1 ⇒ L2 = 2 L1 = (20 cm) = 32.6 cm 323 K T2 T1 T2 T1 T1

17.54. Model: The process in part (a) is isochoric and the process in part (b) is isobaric.

Solve: (a) Initially V1 = (0.20 m)3 = 0.0080 m3 = 8.0 L and T1 = 293 K. Helium has an atomic mass number A = 4, so 3 g of helium is n = M/Mmol = 0.75 mole of helium. We can find the initial pressure from the ideal-gas law: nRT1 (0.75 mol)(8.31 J mol K )(293 K ) p1 = = = 228 kPa = 2.25 atm V1 0.0080 m 3

Heating the gas will raise its temperature. A constant volume process has Q = nCV∆T, so Q 1000 J ∆T = = = 107 K nCV (0.75 mol)(12.5 J mol K ) This raises the final temperature to T2 = T1 + ∆T = 400 K. Because the process is isochoric, p2 p T 400 K = 1 ⇒ p2 = 2 p1 = (2.25 atm) = 3.07 atm 293 K T2 T1 T1 (b) The initial conditions are the same as part a, but now Q = nCP∆T. Thus, Q 1000 J ∆T = = = 64.1 K nCP (0.75 mol)(20.8 J mol K ) Now the final temperature is T2 = T1 + ∆T = 357 K. Because the process is isobaric, V2 V1 T 357 K = ⇒ V2 = 2 V1 = 0.0080 m 3 = 0.00975 m 3 = 9.75 L 293 K T2 T1 T1 (c)

(

)

17.55. Model: For a gas, the thermal energy is the total kinetic energy of the moving molecules.

Solve: At T = 0 K, atoms of the gas have no thermal energy ((Eth)i = 0) and no velocity. Consequently, the pressure due to the atoms of the gas is zero. If we start the gas in a volume of nRTf (2.0 mol)(8.31 J mol K )(310 K ) = Vi = Vf = = 0.05086 m 3 pf 1.013 × 10 5 Pa

(

)

and increase the temperature from Ti = 0 K to Tf = 310 K at constant volume, then the pressure will rise with T as heat Q is added. The amount of heat added at constant volume is Q = nCV ∆T = (2.0 mol)(12.5 J mol K )(310 K ) = 7750 J No work is done, so the first law is ∆Eth = Q + W = Q = 7750 J. The change in thermal energy is ∆Eth = ( Eth )f − ( Eth )i . But (Eth)i = 0, so the thermal energy of the gas is (Eth)f = 7750 J.

17.56. Model: This is an isothermal process.

Solve: (a) The final temperature is T2 = T1 because the process is isothermal. (b) The work done on the gas is V2

V2

nRT1 V dV = − nRT1 ln 2 = −nRT1ln 2 V V1 V1

W = − ∫ pdV = − ∫ V1

(c) From the first law of thermodynamics ∆Eth = W + Q = 0 J because ∆T = 0 K. Thus, the heat energy transferred to the gas is Q = − W = nRT1 ln 2 .

17.57. Model: The gas is an ideal gas and it goes through an isobaric and an isochoric process.

Solve: (a) The initial conditions are p1 = 3.0 atm = 304,000 Pa and T1 = 293 K. Nitrogen has a molar mass Mmol = 28 g/mol, so 5 g of nitrogen gas has n = M/Mmol = 0.1786 mol. From this, we can find the initial volume:

V1 =

nRT1 (0.1786 mol)(8.31 J mol K )(293 K ) = = 1.430 × 10 −3 m 3 = 1430 cm 3 304,000 Pa p1

The volume triples, so V2 = 3V1 = 4290 cm3. The expansion is isobaric (p 2 = p1 = 3.0 atm), so V2 V1 V = ⇒ T2 = 2 T1 = (3)293 K = 879 K = 606°C T2 T1 V1 (b) The process is isobaric, so

Q = nCP ∆T = (0.1786 mol)(29.1 J mol K )(879 K − 293 K ) = 3050 J (c) The pressure is decreased at constant volume (V3 = V2 = 4290 cm3 ) until the original temperature is reached (T3 = T1 = 293 K). For an isochoric process, p3 T p 293 K = 2 ⇒ p3 = 3 p2 = (3.0 atm) = 1.0 atm 879 K T3 T2 T2 (d) The process is isochoric, so Q = nCV ∆T = (0.1786 mol)(20.8 J mol K )(293 K − 879 K ) = −2180 J So, 2180 J of heat was removed to decrease the pressure. (e)

17.58. Model: The gas is an ideal gas. Visualize: Please refer to Figure P17.58. Call the upper right corner (on process A) 2 and the lower left corner (on process B) 3. Solve: The change in thermal energy is the same for any gas process that has the same ∆T. Processes A and B have the same ∆T, since they start and end at the same points, so (∆Eth)A = (∆Eth)B. The first law is then (∆Eth)A = QA + WA = (∆Eth)B = QB + WB ⇒ QA – QB = WB – WA In process B, work W = –p∆V = –pi(2Vi – Vi) = –piVi is done during the isobaric process i → 3. No work is done during the isochoric process 3 → f. Thus WB = –piVi. Similarly, no work is done during the isochoric process i → 2 of process A, but W = –p∆V = –2pi(2Vi – Vi) = –2piVi is done during the isobaric process 2→ f. Thus WA = –2piVi. Combining these, QA – QB = WB – WA = –piVi – (–2piVi) = piVi

17.59. Model: The two processes are isochoric and isobaric. Visualize: Please refer to Figure P17.59. Solve: Process A is isochoric which means

Tf Ti = pf pi ⇒ Tf = Ti ( pf pi ) = Ti (1 atm 3 atm) = 13 Ti

From the ideal-gas equation,

Ti =

5 −6 3 pi Vi (3 × 1.013 × 10 Pa )(2000 × 10 m ) = = 731.4 K ⇒ Tf = 13 Ti = 243.8 K nR (0.10 mol)(8.31 J mol K)

⇒ Tf − Ti = −487.6 K Thus, the heat required for process A is QA = nCV ∆T = (0.10 mol)(20.8 J mol K )( −487.6 K ) = −1010 J Process B is isobaric which means

Tf Vf = Ti Vi ⇒ Tf = Ti (Vf Vi ) = Ti (3000 cm 3 1000 cm 3 ) = 3Ti

From the ideal-gas equation,

Ti =

5 −6 3 pi Vi (2 × 1.013 × 10 Pa )(1000 × 10 m ) = = 243.8 K nR (0.10 mol)(8.31 J mol K) ⇒ Tf = 3Ti = 731.4 K ⇒ Tf − Ti = 487.6 K

Thus, heat required for process B is QB = nCP ∆T = (0.10 mol)(29.1 J mol K )( 487.6 K ) = 1419 J Assess: Heat is transferred out of the gas in process A, but transferred into the gas in process B.

17.60. Model: We have an adiabatic and an isothermal process. Visualize: Please refer to P17.60. Solve: For the adiabatic process, no heat is added or removed. That is Q = 0 J. Isothermal processes occur at a fixed temperature, so ∆T = 0 K. Thus ∆Eth = 0 J, and the first law of thermodynamics gives

Q = −W = nRT ln(Vf Vi )

The temperature T can be obtained from the ideal gas equation as follows:

pi Vi = nRT ⇒ T =

(

)

1.013 × 10 5 Pa (3000 × 10 −6 m 3 ) pi Vi = 366 K = nR (0.10 mol)(8.31 J mol K)

Substituting into the equation for Q we get

 1000 × 10 −6 m 3  Q = (0.10 mol)(8.31 J mol K )(366 K ) ln  = −334 J  3000 × 10 −6 m 3  That is, 334 J of heat energy is removed from the gas.

17.61. Model: The monatomic gas is an ideal gas which is subject to isobaric and isochoric processes. Visualize: Please refer to Figure P17.61. Solve: (a) For this isobaric process, p1 = 4.0 atm, V1 = 800 × 10−6 m3, p2 = 4.0 atm, and V2 = 1600 × 10−6 m3. The temperature T1 of the gas is obtained from the ideal-gas equation as: pV T1 = 1 1 = 390 K nR where n = 0.10 mol. Also,

T2 = T1

 1600 × 10 −6 m 3  V2 = T1   = 2T1 = 780 K V1  800 × 10 −6 m 3 

Thus, the heat required for the process 1 → 2 is

Q = nCP (T2 − T1 ) = (0.10 mol)(29.1 J mol K )(390 K ) = 1135 J

This is heat transferred to the gas. (b) For the isochoric process, V2 = V3 = 1600 × 10−6 m3, p2 = 4.0 atm, p3 = 2.0 atm, and T2 = 780 K. T3 can be obtained from the ideal-gas equation as follows: pV p2 V2 2.0 atm  = 390 K = 3 3 ⇒ T3 = T2 ( p3 p2 ) = (780 K )  4.0 atm  T2 T3 The heat required for the process 2 → 3 is

Q = nCV (T3 − T2 ) = (0.10 mol)(20.8 J / mol K )(390 K − 780 K ) = −811 J

Because of the negative sign, this is the amount of heat removed from the gas. (c) The change in the thermal energy of the gas is

∆Eth = (Q1→2 + Q2→3 ) + (W1→2 + W2→3 ) = 1135 J − 811 J + W1→2 + 0 J = 324 J − p∆V = 324 J – (4.0 × 1.013 × 105 Pa)(1600 × 10−6 m3 – 800 × 10−6 m3) = 0 J Assess: This result was expected since T3 = T1.

17.62. Model: Assume that the gas is an ideal gas. Visualize:

The volume of container A is a constant. On the other hand, heating container B causes the volume to change, but the pressure remains the same. Solve: (a) For the heating of the gas in container A, ∆TA = QA / nCV . Similarly, for the gas in container B, ∆TB = QB / nCP . Because QA = QB and CP > CV, we see that ∆TA > ∆TB . The gases started at the same temperature, so TA > TB. (b)

(c) The pressure in container B exerted by the gas is equal to the pressure on the gas by the piston. That is,

pB = patmos +

w piston Apiston

= 1.013 × 10 5 Pa +

(10 kg)(9.8 m s 2 ) 1.0 × 10 −4 m 2

= 1.081 × 106 Pa

Container A has the same volume, temperature, and number of moles of gas as container B, so PA = PB = 1.081 × 10 6 Pa. (d) The heating of container B is isobaric, so

Vf Vi T = ⇒ Vf = Vi f Tf Ti Ti We have Ti = 293 K, and Tf can be obtained from

Q = P∆t = nCP (Tf − Ti ) The number of moles of gas is n = PV i i / RTi = 0.355 mol. Thus

(25 W )(15 s) = (0.355 mol)(20.8 J mol K)(Tf − 293 K) ⇒ Tf = 344 K ⇒ Vf = (8.0 × 10 −4 m 3 )(344 K 293 K ) = 9.39 × 10−4 m3 = 939 cm3

17.63. Model: Assume that the gas is an ideal gas. A diatomic gas has 1.40. Solve:

(a) For container A,

ViA =

nRTiA (0.10 mol)(8.31 J mol K )(300 K ) = 8.20 × 10 −4 m 3 = 3.0 × 1.013 × 10 5 Pa piA

For an isothermal process pfAVfA = piAViA. This means TfA = TiA = 300 K and

VfA = ViA ( piA pfA ) = (8.20 × 10 −4 m 3 )(3.0 atm 1.0 atm) = 2.46 × 10 −3 m 3 The gas in container B starts with the same initial volume. For an adiabatic process,

p  pfBVfBγ = piBViBγ ⇒ VfB = ViB  iB   pfB 

1

γ

3.0 atm  = (8.20 × 10 −4 m 3 )  1.0 atm 

1 1.40

= 1.80 × 10 −3 m 3

The final temperature TfB can now be obtained by using the ideal-gas equation:

TfB = TiB (b)

pfB VfB 1.0 atm   1.80 × 10 −3 m 3  = (300 K ) = 220 K  3.0 atm   8.20 × 10 −4 m 3  piB ViB

17.64. Model: The gas is assumed to be an ideal gas that is subjected to isobaric and isochoric processes. Visualize: Please refer to Figure P17.64. Solve: (a) The initial conditions are p1 = 3.0 atm = 304,000 Pa, V1 = 100 cm3 = 1.0 × 10−4 m3, and T1 = 100°C = 373 K. The number of moles of gas is

n=

−4 3 p1V1 (304,000 Pa )(1.0 × 10 m ) = 9.81 × 10 −3 mol = RT1 (8.31 J mol K)(373 K)

At point 2 we have p2 = p1 = 3.0 atm and V2 = 300 cm3 = 3V1. This is an isobaric process, so

V2 V1 V = ⇒ T2 = 2 T1 = 3(373 K) = 1119 K T2 T1 V1 The gas is heated to raise the temperature from T1 to T2. The amount of heat required is

Q = nCP ∆T = (9.81 × 10 −3 mol)(20.8 J mol K )(1119 K − 373 K ) = 152 J This amount of heat is added during process 1 → 2. (b) Point 3 returns to T3 = 100°C = 373 K. This is an isochoric process, so

Q = nCV ∆T = (9.81 × 10 −3 mol)(12.5 J mol K )(373 K − 1119 K ) = −91.5 J This amount of heat is removed during process 2 → 3.

17.65. Model: Assume the gas to be an ideal gas. Visualize: Please refer to Figure P17.65. Solve: (a) The work done on the gas is the negative of the area under the p-versus-V graph, that is

W = −area under curve = −50.7 J (b) The change in thermal energy is

∆Eth = nCV ∆T = nCV (Tf − Ti ) Using the ideal-gas law to calculate the initial and final temperatures,

Ti =

5 −6 3 pi Vi ( 4.0 × 1.013 × 10 Pa )(100 × 10 m ) = = 325 K nR (0.015 mol)(8.31 J mol K)

Tf =

(

)

1.013 × 10 5 Pa (300 × 10 −6 m 3 ) pf Vf = = 244 K nR (0.015 mol)(8.31 J mol K)

⇒ ∆Eth = (0.015 mol)(12.5 J mol K )(244 K − 325 K ) = −15.2 J (c) From the first law of thermodynamics, ∆Eth = Q + W ⇒ Q = ∆Eth − W = −15.2 J − ( −50.7 J ) = 35.5 J That is, 35.5 J of heat energy is transferred to the gas.

17.66. Model: Assume that the gas is an ideal gas and that the work, heat, and thermal energy are connected by the first law of thermodynamics. Visualize: Please refer to Figure P17.66. Solve: (a) For point 1, V1 = 1000 cm3 = 1.0 × 10−3 m3, T1 = 133°C = 406 K, and the number of moles is

n=

 120 × 10 −3 g  M =  = 0.030 mol Mmol  4 g / mol 

Thus, the pressure p1 is

nRT1 = 1.012 × 10 5 Pa = 1.0 atm V1 The process 1 → 2 is isochoric (V2 = V1) and p2 = 5p1 = 5.0 atm. Thus, p1 =

T2 = T1 ( p2 p1 ) = ( 406 K )(5) = 2030 K = 1757°C The process 2 → 3 is isothermal (T2 = T3), so V3 = V2(p2/p3) = V2(p2/p1) = 5V2 = 5000 cm3 Point 1 Point 2 Point 3

p (atm)

T (°C)

V (cm3)

1.0 5.0 1.0

133 1757 1757

1000 1000 5000

(b) The work W1→2 = 0 J because it is an isochoric process. The work in process 2 → 3 can be found using Equation 17.16 as follows:

W2→3 = − nRT2 ln(V3 V2 ) = −(0.030 mol)(8.31 J mol K )(2030 K ) ln(5) = −815 J The work in the isobaric process 3 → 1 is

W3→1 = − p(Vf − Vi ) = −(1.012 × 10 5 Pa )(1.0 × 10 −3 m 3 − 5.0 × 10 −3 m 3 ) = 405 J (c) The heat transferred in process 1 → 2 is

Q1→2 = nCV ∆T = (0.030 mol)(12.5 J mol K )(2030 K − 406 K ) = 609 J The heat transferred in the isothermal process 2 → 3 is Q2→3 = − W2→3 = 815 J . The heat transferred in the isobaric process 3 → 1 is Q3→1 = nCP ∆T = (0.030 mol)(20.8 J mol K )( 406 K − 2030 K ) = −1013 J

17.67. Model: The air is assumed to be an ideal diatomic gas that is subjected to an adiabatic process.

Solve: The air admitted into the cylinder at T0 = 30°C = 303 K and p0 = 1 atm = 1.013 × 105 Pa has a volume V0 = 600 × 10−6 m3 and contains pV n = 0 0 = 0.024 mol RT0

Using Equation 17.36 and the fact that Q = 0 J for an adiabatic process,

∆Eth = Q + W = nCV ∆T ⇒ W = nCVT ⇒ 400 J = (0.024 mol)(20.8 J/mol K)(Tf – 303 K) ⇒ Tf = 1100 K For an adiabatic process Equation 17.40 is 1

γ −1 f

Tf V

γ −1 0 0

=TV

1

 T  γ −1 303 K  1.4 −1 = (6.0 × 10 −4 m 3 ) ⇒ Vf = V0  0  = 2.39 × 10 −5 m 3 = 23.9 cm 3  1100 K   Tf 

Assess: Note that W is positive because the environment does work on the gas.

17.68. Model: The gas is an ideal gas that is subjected to an adiabatic process. Solve:

(a) For an adiabatic process, γ

V  p ln(2.5) γ = 1.32 pf V = pi Vi ⇒ f =  i  ⇒ 2.5 = (2.0) ⇒ γ = pi  Vf  ln(2.0) γ f

γ

(b) Equation 17.40 for an adiabatic process is γ −1 f

Tf V

= Ti Vi

γ −1

T V  ⇒ f = i Ti  Vf 

γ −1

= (2.0)

1.32 −1

= (2.0)

0.32

= 1.25

17.69. Model: Air is assumed to be an ideal diatomic gas that is subjected to an adiabatic process. Solve:

(a) Equation 17.40 for an adiabatic process is 1

γ −1 f

Tf V

= Ti Vi

γ −1

V  T  γ −1 ⇒ f = i Vi  Tf 

For the temperature to increase from Ti = 20°C = 293 K to Tf = 1000°C = 1273 K, the compression ratio will be 1

Vf  293 K  1.4 −1 V 1 = = 0.02542 ⇒ max = = 39.3   1273 K Vi Vmin 0.02542 (b) From the Equation 17.39, γ

V  p 1.4 pf V = pi Vi ⇒ f =  i  = (39.3) = 171 pi  Vf  γ f

γ

17.70. Model: The helium gas is assumed to be an ideal gas that is subjected to an isobaric process. Solve:

(a) The number of moles in 2.0 g of helium is

n=

M 2.0 g = = 0.50 mol Mmol 4.0 g mol

At Ti = 100°C = 373 K and pi = 1.0 atm = 1.013 × 105 Pa, the gas has a volume

Vi =

nRTi = 0.0153 m 3 = 15.3 L pi

For an isobaric process (pf = pi) that doubles the volume Vf = 2Vi,

(Tf Ti ) = (Vf

Vi ) = 2 ⇒ Tf = 2Ti = 2(373 K ) = 746 K = 473°C

(b) The work done by the environment on the gas is

W = − pi (Vf − Vi ) = − pi Vi (2 − 1) = −(1.013 × 10 5 Pa )(0.0153 m 3 ) = −1550 J (c) The heat input to the gas is

Q = nCP (Tf − Ti ) = (0.50 mol)(20.8 J mol K )(746 K − 373 K ) = 3880 J (d) The change in the thermal energy of the gas is

∆Eth = Q + W = 3880 J − 1550 J = 2330 J (e)

Assess: The internal energy can also be calculated as follows:

∆Eth = nCV ∆T = (0.5 mol)(12.5 J mol K )(746 K − 373 K ) = 2330 J This is the same result as we got in part (d).

17.71. Model: The helium gas is assumed to be an ideal gas that is subjected to an isothermal process. Solve:

(a) The number of moles in 2.0 g of helium gas is

n=

M 2.0 g = = 0.50 mol Mmol 4.0 g mol

At Ti = 100°C = 373 K and pi = 1.0 atm = 1.013 × 105 Pa, the gas has a volume nRTi Vi = = 0.0153 m 3 = 15.3 L pi For an isothermal process (Tf = Ti) that doubles the volume Vf = 2Vi,

pf Vf = pi Vi ⇒ pf = pi (Vi Vf ) = (1.0 atm)( 12 ) = 0.50 atm (b) The work done by the environment on the gas is

W = − nRTi ln(Vf Vi ) = −(0.50 mol)(8.31 J mol K )(373 K ) ln(2) = −1074 J (c) Because ∆Eth = Q + W = 0 J for an isothermal process, the heat input to the gas is Q = −W = 1074 J. (d) The change in internal energy ∆Eth = 0 J. (e)

17.72. Model: The nitrogen gas is assumed to be an ideal gas that is subjected to an adiabatic process. Solve:

(a) The number of moles in 14.0 g of N2 gas is

n=

M 14.0 g = = 0.50 mol Mmol 28 g mol

At Ti = 273 K and pi = 1.0 atm = 1.013 × 105 Pa, the gas has a volume nRTi Vi = = 0.0112 m 3 = 11.2 L pi For an adiabatic process that compresses to a pressure pf = 20 atm, we can use Equation 17.39 and Equation 17.40 as follows: γ −1 f

Tf V

= Ti Vi

γ −1

T  V  ⇒ f = i  Ti   Vf 

γ −1

1

 p γ V pf V = pi Vi ⇒  f  = i Vf  pi  γ f

γ

Combining the above two equations yields

(Tf Ti ) = ( pf

pi )

γ −1 γ

⇒ Tf = Ti (20)

1.4 −1.0 1.4

= Ti (2.3535) = 643 K

(b) The work done on the gas is

W = ∆Eth = nCV (Tf − Ti ) = (0.50 mol)(20.8 J mol K )(643 K − 273 K ) = 3850 J (c) The heat input to the gas is Q = 0 J. (d) From the above equation, 1

1 Vi  pf  γ V =   = (20) 1.4 = 8.50 = max Vf  pi  Vmin

(e)

17.73. Model: The gas is assumed to be an ideal gas that is subjected to an isochoric process. Solve:

(a) The number of moles in 14.0 g of N2 gas is

n=

M 14.0 g = = 0.50 mol Mmol 28 g mol

At Ti = 273 K and pi = 1.0 atm = 1.013 × 105 Pa, the gas has a volume

Vi =

nRTi = 0.0112 m 3 = 11.2 L pi

For an isochoric process (Vi = Vf),

Tf p 20 atm = f = = 20 ⇒ Tf = 20(273 K ) = 5460 K 1 atm Ti pi (b) The work done on the gas is W = − p∆V = 0 J. (c) The heat input to the gas is

Q = nCV (Tf − Ti ) = (0.50 mol)(20.8 J mol K )(5460 K − 273 K ) = 5.39 × 10 4 J (d) The pressure ratio is

pmax p 20 atm = f = = 20 1 atm pmin pi (e)

17.74. Model: The air is assumed to be an ideal gas. Because the air is compressed without time to exchange heat with its surroundings, the compression is an adiabatic process. Solve: The initial pressure of air in the mountains behind Los Angeles is pi = 60 × 10 3 Pa at Ti = 273 K. The pressure of this air when it is carried down to the elevation near sea level is pf = 100 × 103 Pa. The adiabatic compression of a gas leads to an increase in temperature according to Equation 17.39 and Equation 17.40, which are γ −1 f

Tf V

= Ti Vi

γ −1

T  V  ⇒ f = i  Ti   Vf 

γ −1

1

 p γ V pf V = pi Vi ⇒  f  = i Vf  pi  γ f

γ

Combining these two equations,

(Tf Ti ) = ( pf

pi )

γ −1 γ

 100 × 10 3 Pa  ⇒ Tf = Ti    60 × 10 3 Pa 

1.4 −1 1.4

 5 = (273 K )  3

0.286

= 316 K = 43°C = 109°F

17.75. Solve: (a) 50 J of work are done on a gas to compress it to one-third of its original volume at a constant temperature of 77°C. How many moles of the gas are in the sample? (b) The number of moles is n=

50 J = 0.0156 mol −(8.31 J mol K )(350 K )(ln 13 )

17.76. Solve: (a) A heated 500 g iron slug is dropped into a 200 cm3 pool of mercury at 15째C. If the mercury temperature rises to 90째C, what was the initial temperature of the iron slug? (b) The initial temperature was 217째C .

17.77. Solve: (a) 2.0 Ă— 10 5 J must be removed from a sample of nitrogen gas at 20°C to convert it to liquid nitrogen. What is the mass of the sample? (b) The mass is M = 0.472 kg.

17.78. Solve: (a) A diatomic gas is adiabatically compressed from 1 atm pressure to 10 atm pressure. What is the compression ratio Vmax/Vmin? 1

(b) The ratio is Vmax Vmin = 10 1.4 = 5.18 .

17.79. Model: Assume the helium gas to be an ideal gas. The gas is subjected to isothermal, isochoric, and adiabatic processes. Visualize: Please refer to Figure CP17.79. The gas at point 1 has volume V1 = 1000 cm3 = 1.0 × 10−3 m3 and pressure p1 = 3.0 atm. At point 2, V2 = 3000 cm3 = 3.0 × 10−3 m3 and p2 = 1.0 atm. These values mean that T2 = T1, so process 1 → 2 is an isothermal process. The process 2 → 3 occurs at constant volume and is thus an isochoric process. Finally, because temperature T3 is lower than T1 or T2, the process 3 → 1 is an adiabatic process. Solve: (a) The number of moles of gas is

n=

0.120 g = 0.030 mols 4 g mol

The temperature T1 can be calculated to be

T1 =

(

)

3.0 × 1.013 × 10 5 Pa (1.0 × 10 −3 m 3 ) p1V1 = 1219 K = 946°C = nR (0.030 mol)(8.31 J mol K)

For the isothermal process 1 → 2, T2 = 1219 K. For the adiabatic process 3 → 1,

p3 = p1 (V1 V3 )

γ

 1000 cm 3  = (3.0 atm)   3000 cm 3 

1.67

= 0.48 atm

T3 = T1 (V1 V3 )

γ −1

= (1219 K )( 13 )

0.67

Point

p (atm)

T (°C)

V (cm3)

1 2 3

3.0 1.0 0.48

946 946 310

1000 3000 3000

= 583 K = 310°C

Note that the values obtained above are consistent with the isochoric process 2 → 3, for which

p p2 = 3 ⇒ p2 = (T2 T3 ) p3 = (1219 K 583 K )(0.48 atm) = 1 atm T2 T3 (b) From Equation 17.15,

V  W1→2 = − nRT1 ln 2  = −(0.030 mol)(8.31 J mol K )(1219 K ) ln(3) = −334 J  V1  The work done in the ischochoric process is W2→3 = 0 J . The work done in the adiabatic process is

W3→1 = nCV (T1 − T3 ) = (0.030 mol)(12.5 J mol K )(1219 K − 583 K ) = 239 J (c) For the process 1 → 2, ∆T = 0 K ⇒ ∆Eth = 0 J ⇒ Q = − W = 334 J For the process 2 → 3, W = 0 J,

∆Eth = Q = nCV (T3 − T2 ) = −239 J

For the process 3 → 1, Q = 0 J.

17.80. Model: The gas is an ideal gas, and its thermal energy is the total kinetic energy of the moving molecules. Visualize: Please refer to Figure P17.80. Solve: (a) The piston is floating in static equilibrium, so the downward force of gravity on the piston’s mass must exactly balance the upward force of the gas, Fgas = pA where A = πr2 is the area of the face of the piston. Since the upper part of the cylinder is evacuated, there is no gas pressure force pushing downward. Thus,

M piston g = pA ⇒ p =

M piston g A

=

ρ Cu Vpiston g A

= ρ Cu gh = (8920 kg m 3 )(9.80 m s 2 )(0.040 m ) = 3500 Pa

(b) The gas volume is V1 = πr 2 L = π (0.030) 2 (0.20 m ) = 5.65 × 10 −4 m 3 . The number of moles is

n=

−4 3 p1V1 (3500 Pa )(5.65 × 10 m ) = 8.12 × 10 −4 mol = RT1 (8.31 J mol K)(293 K)

The number of molecules is N = nNA = (8.12 × 10−4 mol)(6.02 × 1023 mol−1) = 4.89 × 1020 (c) The thermal energy is

( )

Eth = NK avg = N 12 m vavg

2

Molecular nitrogen N2 has an atomic mass number of A = 28, so the mass of one molecule is m = 28 × (1.661 × 10−27 kg) = 4.65 × 10−26 kg If the average speed is vavg = 550 m/s, then the thermal energy is Eth = (4.89 × 1020)(0.5)(4.65 × 10−26 kg)(550 m/s)2 = 3.44 J (d) The pressure in the gas is determined simply by the weight of the piston. That will not change as heat is added, so the heating takes place at constant pressure with Q = nCP∆T. The temperature increase is

∆T =

Q 2.0 J = = 85 K nCP (8.12 × 10 −4 mol)(29.1 J mol K )

This raises the gas temperature to T2 = T1 + ∆T = 378 K = 105°C. (e) Noting that the volume of a cylinder is V = πr2L and that r doesn’t change, the ideal gas relationship for an isobaric process is

V2 V1 L L T 378 K  = ⇒ 2 = 1 ⇒ L2 = 2 L1 =  20 cm = 25.8 cm  293 K  T2 T1 T2 T1 T1 (f) The work done by the gas is Wgas = Fgas ∆y . The force exerted on the piston by the gas is

Fgas = pA = pπr 2 = 9.90 N This force is applied through ∆y = 5.8 cm = 0.058 m, so the work done is Wgas = (9.90 N)(0.058 m) = 0.574 J Thus, 0.574 J is the work done by the gas on the piston. The work done on the gas is −0.574 J.

17.81. Model: There is a thermal interaction between the iron, assumed to be initially at room temperature

(20°C), and the liquid nitrogen. The boiling point of liquid nitrogen is –196°C = 77 K. Solve: The piece of iron has mass Miron = 197 g = 0.197 kg and volume Viron = Miron/ρiron = (0.197 kg)/(7870 kg/m3) = 25 × 10−6 m3 = 25 cm3 = 25 mL. The heat lost by the iron is Qiron = Mironciron∆T = (0.197 kg)(449 J/kg K)(77 K – 293 K) = –1.911 × 104 J This heat causes mass M of the liquid nitrogen to boil. Energy conservation requires

Qiron + QN2 = Qiron + MLf = 0 ⇒ M = −

Qiron 1.911 × 10 4 J = = 0.0960 kg 1.99 × 10 5 J / kg Lf

The volume of liquid nitrogen boiled away is thus

Vboil =

M 0.0960 kg = = 1.19 × 10 −4 m 3 = 119 mL ρ N2 810 kg / m 3

Now the volume of nitrogen gas (at 77 K) is 1500 mL before the iron is dropped in. The volume of the piece of iron excludes 25 mL of gas, so the initial gas volume, when the lid is sealed and the liquid starts to boil, is V1 = 1475 mL. The pressure is p1 = 1.0 atm and the temperature is T1 = 77 K. Thus the number of moles of nitrogen gas is

n1 =

p1V1 (101, 300 Pa)(1.475 × 10 −3 m 3 ) = = 0.234 mol (8.31 J / mol K)(77 K) RT1

119 mL of liquid boils away, so the gas volume increases to V2 = V1 + Vboil = 1475 mL + 119 mL = 1594 mL. The temperature is still T2 = 77 K, but the number of moles of gas has been increased by the liquid that boiled. The number of moles that boiled away is

nboil =

96.0 g = 3.429 mol 28 mol / g

Thus the number of moles of nitrogen gas increases to n2 = n1 + nboil = 0.234 mol + 3.429 mol = 3.663 mol. Consequently, the gas pressure increases to

p2 =

n2 RT2 (3.663 mol)(8.31 J / mol K)(77 K) = = 1.470 × 10 6 Pa = 14.5 atm 1.594 × 10 −3 m 3 V2

Assess: Don’t try this! The large pressure increase could cause a flask of liquid nitrogen to explode, leading to serious injuries.