301. A gas has pressure \(P=1.0\times10^5\,\text{Pa}\), density \(\rho=1.25\,\text{kg m}^{-3}\), and molar mass \(M=32\times10^{-3}\,\text{kg mol}^{-1}\). Its rms speed and temperature are to be compared using \(R=8.0\,\text{J mol}^{-1}\text{K}^{-1}\). The closest pair is
ⓐ. \(v_{\text{rms}}\approx280\,\text{m s}^{-1}\), \(T\approx320\,\text{K}\)
ⓑ. \(v_{\text{rms}}\approx490\,\text{m s}^{-1}\), \(T\approx40\,\text{K}\)
ⓒ. \(v_{\text{rms}}\approx850\,\text{m s}^{-1}\), \(T\approx320\,\text{K}\)
ⓓ. \(v_{\text{rms}}\approx490\,\text{m s}^{-1}\), \(T\approx320\,\text{K}\)
Correct Answer: \(v_{\text{rms}}\approx490\,\text{m s}^{-1}\), \(T\approx320\,\text{K}\)
Explanation: \( \textbf{Given:} \) \(P=1.0\times10^5\,\text{Pa}\), \(\rho=1.25\,\text{kg m}^{-3}\), and \(M=32\times10^{-3}\,\text{kg mol}^{-1}\).
\( \textbf{First relation for rms speed:} \)
\[
v_{\text{rms}}=\sqrt{\frac{3P}{\rho}}
\]
\( \textbf{Substitution:} \)
\[
v_{\text{rms}}=\sqrt{\frac{3(1.0\times10^5)}{1.25}}
\]
\( \textbf{Inside square root:} \)
\[
\frac{3.0\times10^5}{1.25}=2.4\times10^5
\]
\( \textbf{Speed:} \)
\[
v_{\text{rms}}\approx\sqrt{2.4\times10^5}\approx490\,\text{m s}^{-1}
\]
\( \textbf{Density-temperature relation:} \)
\[
\rho=\frac{PM}{RT}
\]
\( \textbf{Rearrange for } T \textbf{:} \)
\[
T=\frac{PM}{\rho R}
\]
\( \textbf{Substitution:} \)
\[
T=\frac{(1.0\times10^5)(32\times10^{-3})}{(1.25)(8.0)}
\]
\( \textbf{Calculation:} \)
\[
T=\frac{3200}{10}=320\,\text{K}
\]
\( \textbf{Final answer:} \) The closest pair is \(v_{\text{rms}}\approx490\,\text{m s}^{-1}\) and \(T\approx320\,\text{K}\).
302. In a dilute gas, thermal conduction is explained microscopically by molecules
ⓐ. becoming motionless in the warmer region
ⓑ. transferring heat only by visible light emission
ⓒ. losing their molecular identity during every collision
ⓓ. carrying energy from warmer to cooler regions
Correct Answer: carrying energy from warmer to cooler regions
Explanation: Gas molecules in a warmer region have higher average kinetic energy than those in a cooler region. Random molecular motion and collisions allow energy to be transferred from one region to another. This microscopic transfer appears macroscopically as thermal conduction. The process does not require molecules to lose their identity or stop moving. Kinetic theory describes conduction in gases as energy transport by moving and colliding molecules.
303. A model-boundary statement says, “Equipartition must give the exact heat capacity of every substance at every temperature.” The best correction is that equipartition
ⓐ. classical equipartition has limits
ⓑ. does not apply to any ideal gas
ⓒ. replaces the need for temperature measurement
ⓓ. says every substance has \(C=R\)
Correct Answer: classical equipartition has limits
Explanation: Equipartition is a classical result that assigns \(\frac{1}{2}k_BT\) per active quadratic degree of freedom. It works well for many ideal-gas heat-capacity predictions when the relevant modes are active. However, real substances, low-temperature behaviour, liquids, and complex solids may not follow the simplest prediction exactly. Some modes can be inactive over a given temperature range, and molecular interactions can matter strongly. The model is useful when its assumptions fit the physical situation.
304. A \(0.020\,\text{m}^3\) vessel contains an ideal gas at \(P=1.5\times10^5\,\text{Pa}\) and \(T=300\,\text{K}\). The gas is monatomic. Using \(R=8.3\,\text{J mol}^{-1}\text{K}^{-1}\), the internal energy of the gas is closest to
ⓐ. \(3.0\times10^3\,\text{J}\)
ⓑ. \(4.5\times10^3\,\text{J}\)
ⓒ. \(6.0\times10^3\,\text{J}\)
ⓓ. \(9.0\times10^3\,\text{J}\)
Correct Answer: \(4.5\times10^3\,\text{J}\)
Explanation: \( \textbf{Given pressure:} \) \(P=1.5\times10^5\,\text{Pa}\).
\( \textbf{Given volume:} \) \(V=0.020\,\text{m}^3\).
\( \textbf{Given temperature:} \) \(T=300\,\text{K}\).
\( \textbf{Gas type:} \) Monatomic ideal gas.
\( \textbf{First relation:} \)
\[
PV=nRT
\]
\( \textbf{Internal energy relation:} \)
\[
U=\frac{3}{2}nRT
\]
\( \textbf{Eliminate } nRT \textbf{ using } PV=nRT \textbf{:} \)
\[
U=\frac{3}{2}PV
\]
\( \textbf{Substitution:} \)
\[
U=\frac{3}{2}(1.5\times10^5)(0.020)
\]
\( \textbf{Product } PV \textbf{:} \)
\[
PV=3.0\times10^3\,\text{J}
\]
\( \textbf{Internal energy:} \)
\[
U=1.5(3.0\times10^3)=4.5\times10^3\,\text{J}
\]
\( \textbf{Final answer:} \) The internal energy is \(4.5\times10^3\,\text{J}\), and \(R\) is not needed after \(PV=nRT\) is combined with \(U=\frac{3}{2}nRT\).
305. A fixed amount of ideal gas changes from \(P_1=1.0\times10^5\,\text{Pa}\), \(V_1=4.0\times10^{-3}\,\text{m}^3\), \(T_1=300\,\text{K}\) to \(P_2=2.0\times10^5\,\text{Pa}\), \(T_2=600\,\text{K}\). What is \(V_2\)?
ⓐ. \(2.0\times10^{-3}\,\text{m}^3\)
ⓑ. \(4.0\times10^{-3}\,\text{m}^3\)
ⓒ. \(8.0\times10^{-3}\,\text{m}^3\)
ⓓ. \(1.6\times10^{-2}\,\text{m}^3\)
Correct Answer: \(4.0\times10^{-3}\,\text{m}^3\)
Explanation: \( \textbf{Initial state:} \) \(P_1=1.0\times10^5\,\text{Pa}\), \(V_1=4.0\times10^{-3}\,\text{m}^3\), and \(T_1=300\,\text{K}\).
\( \textbf{Final data:} \) \(P_2=2.0\times10^5\,\text{Pa}\) and \(T_2=600\,\text{K}\).
\( \textbf{Condition:} \) Amount of gas is fixed.
\( \textbf{Combined gas relation:} \)
\[
\frac{P_1V_1}{T_1}=\frac{P_2V_2}{T_2}
\]
\( \textbf{Rearrange for } V_2 \textbf{:} \)
\[
V_2=V_1\frac{P_1}{P_2}\frac{T_2}{T_1}
\]
\( \textbf{Substitution:} \)
\[
V_2=(4.0\times10^{-3})\left(\frac{1.0\times10^5}{2.0\times10^5}\right)\left(\frac{600}{300}\right)
\]
\( \textbf{Pressure ratio:} \)
\[
\frac{1.0\times10^5}{2.0\times10^5}=\frac{1}{2}
\]
\( \textbf{Temperature ratio:} \)
\[
\frac{600}{300}=2
\]
\( \textbf{Combined factor:} \)
\[
\frac{1}{2}\times2=1
\]
\( \textbf{Final answer:} \) \(V_2=4.0\times10^{-3}\,\text{m}^3\), because doubling pressure and doubling absolute temperature balance each other for fixed \(n\).
306. An ideal gas has density \(1.6\,\text{kg m}^{-3}\) at pressure \(2.4\times10^5\,\text{Pa}\). Its rms speed is
ⓐ. \(450\,\text{m s}^{-1}\)
ⓑ. \(550\,\text{m s}^{-1}\)
ⓒ. \(670\,\text{m s}^{-1}\)
ⓓ. \(900\,\text{m s}^{-1}\)
Correct Answer: \(670\,\text{m s}^{-1}\)
Explanation: \( \textbf{Given pressure:} \) \(P=2.4\times10^5\,\text{Pa}\).
\( \textbf{Given density:} \) \(\rho=1.6\,\text{kg m}^{-3}\).
\( \textbf{Required:} \) \(v_{\text{rms}}\).
\( \textbf{Kinetic-theory pressure relation:} \)
\[
P=\frac{1}{3}\rho v_{\text{rms}}^2
\]
\( \textbf{Rearrange for squared rms speed:} \)
\[
v_{\text{rms}}^2=\frac{3P}{\rho}
\]
\( \textbf{Substitution:} \)
\[
v_{\text{rms}}^2=\frac{3(2.4\times10^5)}{1.6}
\]
\( \textbf{Numerator:} \)
\[
3(2.4\times10^5)=7.2\times10^5
\]
\( \textbf{Division:} \)
\[
v_{\text{rms}}^2=4.5\times10^5\,\text{m}^2\text{s}^{-2}
\]
\( \textbf{Square root:} \)
\[
v_{\text{rms}}=\sqrt{4.5\times10^5}\approx6.7\times10^2\,\text{m s}^{-1}
\]
\( \textbf{Final answer:} \) The rms speed is approximately \(670\,\text{m s}^{-1}\).
307. A gas molecule has mass \(4.0\times10^{-26}\,\text{kg}\). At a certain temperature its rms speed is \(600\,\text{m s}^{-1}\). Taking \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\), the temperature of the gas is closest to
ⓐ. \(230\,\text{K}\)
ⓑ. \(350\,\text{K}\)
ⓒ. \(520\,\text{K}\)
ⓓ. \(700\,\text{K}\)
Correct Answer: \(350\,\text{K}\)
Explanation: \( \textbf{Mass of one molecule:} \) \(m=4.0\times10^{-26}\,\text{kg}\).
\( \textbf{Rms speed:} \) \(v_{\text{rms}}=600\,\text{m s}^{-1}\).
\( \textbf{Boltzmann constant:} \) \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\).
\( \textbf{Required:} \) Temperature \(T\).
\( \textbf{Rms-speed relation:} \)
\[
v_{\text{rms}}^2=\frac{3k_BT}{m}
\]
\( \textbf{Rearrange for } T \textbf{:} \)
\[
T=\frac{mv_{\text{rms}}^2}{3k_B}
\]
\( \textbf{Square of speed:} \)
\[
v_{\text{rms}}^2=(600)^2=3.6\times10^5\,\text{m}^2\text{s}^{-2}
\]
\( \textbf{Substitution:} \)
\[
T=\frac{(4.0\times10^{-26})(3.6\times10^5)}{3(1.38\times10^{-23})}
\]
\( \textbf{Numerator:} \)
\[
(4.0\times10^{-26})(3.6\times10^5)=1.44\times10^{-20}
\]
\( \textbf{Denominator:} \)
\[
3(1.38\times10^{-23})=4.14\times10^{-23}
\]
\( \textbf{Calculation:} \)
\[
T=\frac{1.44\times10^{-20}}{4.14\times10^{-23}}\approx3.5\times10^2\,\text{K}
\]
\( \textbf{Final answer:} \) The temperature is closest to \(350\,\text{K}\).
308. A fixed sample of ideal gas is compressed isothermally from \(6.0\,\text{L}\) to \(2.0\,\text{L}\). If its initial mean free path is \(\lambda\), the final mean free path and final pressure are respectively
ⓐ. \(3\lambda\) and \(\frac{P_1}{3}\)
ⓑ. \(\frac{\lambda}{9}\) and \(3P_1\)
ⓒ. \(\lambda\) and \(P_1\)
ⓓ. \(\frac{\lambda}{3}\) and \(3P_1\)
Correct Answer: \(\frac{\lambda}{3}\) and \(3P_1\)
Explanation: \( \textbf{Initial volume:} \) \(V_1=6.0\,\text{L}\).
\( \textbf{Final volume:} \) \(V_2=2.0\,\text{L}\).
\( \textbf{Condition:} \) Isothermal compression with fixed number of molecules.
\( \textbf{Pressure relation:} \)
\[
P_1V_1=P_2V_2
\]
\( \textbf{Pressure ratio:} \)
\[
\frac{P_2}{P_1}=\frac{V_1}{V_2}=\frac{6.0}{2.0}=3
\]
\( \textbf{Number-density relation:} \)
\[
n_v=\frac{N}{V}
\]
\( \textbf{Density ratio:} \)
\[
\frac{n_{v2}}{n_{v1}}=\frac{V_1}{V_2}=3
\]
\( \textbf{Mean-free-path dependence:} \)
\[
\lambda\propto\frac{1}{n_v}
\]
\( \textbf{Mean-free-path ratio:} \)
\[
\lambda_2=\frac{\lambda_1}{3}
\]
\( \textbf{Final answer:} \) The final mean free path is \(\frac{\lambda}{3}\) and the final pressure is \(3P_1\).
309. A diatomic ideal gas at ordinary temperature has \(2.0\,\text{mol}\) at \(400\,\text{K}\). If \(R=8.3\,\text{J mol}^{-1}\text{K}^{-1}\), its internal energy and \(C_V\) are closest to
ⓐ. \(1.66\times10^4\,\text{J}\) and \(\frac{5}{2}R\)
ⓑ. \(9.96\times10^3\,\text{J}\) and \(\frac{3}{2}R\)
ⓒ. \(2.32\times10^4\,\text{J}\) and \(\frac{7}{2}R\)
ⓓ. \(6.64\times10^3\,\text{J}\) and \(R\)
Correct Answer: \(1.66\times10^4\,\text{J}\) and \(\frac{5}{2}R\)
Explanation: \( \textbf{Gas type:} \) Diatomic ideal gas at ordinary temperature.
\( \textbf{Active degrees of freedom:} \) \(f=5\).
\( \textbf{Given amount and temperature:} \) \(n=2.0\,\text{mol}\), \(T=400\,\text{K}\).
\( \textbf{Constant-volume heat capacity:} \)
\[
C_V=\frac{f}{2}R=\frac{5}{2}R
\]
\( \textbf{Internal energy relation:} \)
\[
U=\frac{f}{2}nRT
\]
\( \textbf{Substitution:} \)
\[
U=\frac{5}{2}(2.0)(8.3)(400)
\]
\( \textbf{Coefficient simplification:} \)
\[
\frac{5}{2}\times2.0=5
\]
\( \textbf{Calculation:} \)
\[
U=5(8.3)(400)=16600\,\text{J}
\]
\( \textbf{Scientific notation:} \)
\[
U=1.66\times10^4\,\text{J}
\]
\( \textbf{Final answer:} \) The internal energy is \(1.66\times10^4\,\text{J}\), and \(C_V=\frac{5}{2}R\).
310. A gas mixture in a rigid vessel contains \(1.0\,\text{mol}\) helium and \(1.0\,\text{mol}\) hydrogen at the same temperature \(T\). If their molar masses are \(4\times10^{-3}\,\text{kg mol}^{-1}\) and \(2\times10^{-3}\,\text{kg mol}^{-1}\), the ratio \(v_{\text{rms,He}}:v_{\text{rms,H}_2}\) is
ⓐ. \(1:\sqrt{2}\)
ⓑ. \(\sqrt{2}:1\)
ⓒ. \(1:2\)
ⓓ. \(2:1\)
Correct Answer: \(1:\sqrt{2}\)
Explanation: \( \textbf{Molar mass of helium:} \) \(M_{\text{He}}=4\times10^{-3}\,\text{kg mol}^{-1}\).
\( \textbf{Molar mass of hydrogen:} \) \(M_{\text{H}_2}=2\times10^{-3}\,\text{kg mol}^{-1}\).
\( \textbf{Same-temperature condition:} \) Both gases in the mixture have the same \(T\).
\( \textbf{Rms-speed relation:} \)
\[
v_{\text{rms}}=\sqrt{\frac{3RT}{M}}
\]
\( \textbf{Ratio setup:} \)
\[
\frac{v_{\text{rms,He}}}{v_{\text{rms,H}_2}}=\sqrt{\frac{M_{\text{H}_2}}{M_{\text{He}}}}
\]
\( \textbf{Substitution:} \)
\[
\frac{v_{\text{rms,He}}}{v_{\text{rms,H}_2}}=\sqrt{\frac{2\times10^{-3}}{4\times10^{-3}}}
\]
\( \textbf{Simplification:} \)
\[
\frac{v_{\text{rms,He}}}{v_{\text{rms,H}_2}}=\sqrt{\frac{1}{2}}=\frac{1}{\sqrt{2}}
\]
\( \textbf{Final answer:} \) The ratio is \(1:\sqrt{2}\), so hydrogen has the larger rms speed at the same temperature.
311. A monatomic ideal gas expands at constant pressure from \(2.0\times10^{-3}\,\text{m}^3\) to \(5.0\times10^{-3}\,\text{m}^3\) against pressure \(1.0\times10^5\,\text{Pa}\). The change in internal energy is
ⓐ. \(150\,\text{J}\)
ⓑ. \(300\,\text{J}\)
ⓒ. \(450\,\text{J}\)
ⓓ. \(750\,\text{J}\)
Correct Answer: \(450\,\text{J}\)
Explanation: \( \textbf{Gas type:} \) Monatomic ideal gas.
\( \textbf{Pressure:} \) \(P=1.0\times10^5\,\text{Pa}\).
\( \textbf{Initial volume:} \) \(V_1=2.0\times10^{-3}\,\text{m}^3\).
\( \textbf{Final volume:} \) \(V_2=5.0\times10^{-3}\,\text{m}^3\).
\( \textbf{At constant pressure:} \)
\[
\Delta(PV)=P\Delta V
\]
\( \textbf{For a monatomic ideal gas:} \)
\[
U=\frac{3}{2}nRT=\frac{3}{2}PV
\]
\( \textbf{Therefore:} \)
\[
\Delta U=\frac{3}{2}P\Delta V
\]
\( \textbf{Volume change:} \)
\[
\Delta V=5.0\times10^{-3}-2.0\times10^{-3}=3.0\times10^{-3}\,\text{m}^3
\]
\( \textbf{Substitution:} \)
\[
\Delta U=\frac{3}{2}(1.0\times10^5)(3.0\times10^{-3})
\]
\( \textbf{Calculation:} \)
\[
\Delta U=1.5(300)=450\,\text{J}
\]
\( \textbf{Final answer:} \) The change in internal energy is \(450\,\text{J}\).
312. An ideal gas has pressure \(P\) and density \(\rho\). Its rms speed is \(v\). If pressure is made \(4P\) and density is made \(\rho\), the new rms speed is
ⓐ. \(v\)
ⓑ. \(2v\)
ⓒ. \(4v\)
ⓓ. \(\frac{v}{2}\)
Correct Answer: \(2v\)
Explanation: \( \textbf{Starting relation:} \)
\[
P=\frac{1}{3}\rho v_{\text{rms}}^2
\]
\( \textbf{Initial state:} \)
\[
P=\frac{1}{3}\rho v^2
\]
\( \textbf{Final state:} \)
\[
4P=\frac{1}{3}\rho v_2^2
\]
\( \textbf{Divide final equation by initial equation:} \)
\[
\frac{4P}{P}=\frac{v_2^2}{v^2}
\]
\( \textbf{Simplification:} \)
\[
4=\frac{v_2^2}{v^2}
\]
\( \textbf{Taking positive square root:} \)
\[
v_2=2v
\]
\( \textbf{Final answer:} \) The new rms speed is \(2v\), because pressure is proportional to \(v_{\text{rms}}^2\) when density is fixed.
313. A gas has \(N=5.0\times10^{23}\) molecules in volume \(0.025\,\text{m}^3\) at \(T=320\,\text{K}\). Using \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\), its pressure is closest to
ⓐ. \(4.4\times10^4\,\text{Pa}\)
ⓑ. \(8.8\times10^4\,\text{Pa}\)
ⓒ. \(1.8\times10^5\,\text{Pa}\)
ⓓ. \(3.5\times10^5\,\text{Pa}\)
Correct Answer: \(8.8\times10^4\,\text{Pa}\)
Explanation: \( \textbf{Number of molecules:} \) \(N=5.0\times10^{23}\).
\( \textbf{Volume:} \) \(V=0.025\,\text{m}^3\).
\( \textbf{Temperature:} \) \(T=320\,\text{K}\).
\( \textbf{Boltzmann constant:} \) \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\).
\( \textbf{Molecule-scale ideal-gas equation:} \)
\[
PV=Nk_BT
\]
\( \textbf{Rearrange for pressure:} \)
\[
P=\frac{Nk_BT}{V}
\]
\( \textbf{Substitution:} \)
\[
P=\frac{(5.0\times10^{23})(1.38\times10^{-23})(320)}{0.025}
\]
\( \textbf{First product:} \)
\[
(5.0\times10^{23})(1.38\times10^{-23})=6.9
\]
\( \textbf{Numerator:} \)
\[
6.9(320)=2208\,\text{J}
\]
\( \textbf{Pressure:} \)
\[
P=\frac{2208}{0.025}=88320\,\text{Pa}
\]
\( \textbf{Final answer:} \) The pressure is closest to \(8.8\times10^4\,\text{Pa}\).
314. A gas at \(300\,\text{K}\) has molecular diameter \(3.0\times10^{-10}\,\text{m}\). Its pressure is \(1.38\times10^5\,\text{Pa}\). Using \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\) and \(\sqrt{2}\pi\approx4.4\), its mean free path is closest to
ⓐ. \(1.0\times10^{-8}\,\text{m}\)
ⓑ. \(1.0\times10^{-7}\,\text{m}\)
ⓒ. \(1.0\times10^{-6}\,\text{m}\)
ⓓ. \(1.0\times10^{-5}\,\text{m}\)
Correct Answer: \(1.0\times10^{-7}\,\text{m}\)
Explanation: \( \textbf{Given temperature:} \) \(T=300\,\text{K}\).
\( \textbf{Given pressure:} \) \(P=1.38\times10^5\,\text{Pa}\).
\( \textbf{Molecular diameter:} \) \(d=3.0\times10^{-10}\,\text{m}\).
\( \textbf{Number density relation:} \)
\[
n_v=\frac{P}{k_BT}
\]
\( \textbf{Substitution for number density:} \)
\[
n_v=\frac{1.38\times10^5}{(1.38\times10^{-23})(300)}
\]
\( \textbf{Simplification:} \)
\[
n_v=\frac{10^5}{300\times10^{-23}}=\frac{1}{3}\times10^{26}\approx3.33\times10^{25}\,\text{m}^{-3}
\]
\( \textbf{Mean-free-path relation:} \)
\[
\lambda=\frac{1}{\sqrt{2}\pi d^2n_v}
\]
\( \textbf{Square of diameter:} \)
\[
d^2=(3.0\times10^{-10})^2=9.0\times10^{-20}\,\text{m}^2
\]
\( \textbf{Denominator estimate:} \)
\[
(4.4)(9.0\times10^{-20})(3.33\times10^{25})\approx1.32\times10^7\,\text{m}^{-1}
\]
\( \textbf{Reciprocal:} \)
\[
\lambda\approx7.6\times10^{-8}\,\text{m}
\]
\( \textbf{Final answer:} \) The mean free path is closest to \(1.0\times10^{-7}\,\text{m}\).
315. A monatomic ideal gas and a diatomic ideal gas at ordinary temperature each contain \(3.0\,\text{mol}\) and are heated by \(80\,\text{K}\) at constant volume. Using \(R=8.3\,\text{J mol}^{-1}\text{K}^{-1}\), the difference in heat supplied to the two gases is
ⓐ. \(3.98\times10^3\,\text{J}\)
ⓑ. \(5.98\times10^3\,\text{J}\)
ⓒ. \(7.97\times10^3\,\text{J}\)
ⓓ. \(1.99\times10^3\,\text{J}\)
Correct Answer: \(1.99\times10^3\,\text{J}\)
Explanation: \( \textbf{Amount of each gas:} \) \(n=3.0\,\text{mol}\).
\( \textbf{Temperature rise:} \) \(\Delta T=80\,\text{K}\).
\( \textbf{Monatomic constant-volume heat capacity:} \)
\[
C_{V,\text{mono}}=\frac{3}{2}R
\]
\( \textbf{Diatomic constant-volume heat capacity:} \)
\[
C_{V,\text{dia}}=\frac{5}{2}R
\]
\( \textbf{Difference in heat at constant volume:} \)
\[
\Delta Q=n(C_{V,\text{dia}}-C_{V,\text{mono}})\Delta T
\]
\( \textbf{Heat-capacity difference:} \)
\[
C_{V,\text{dia}}-C_{V,\text{mono}}=\frac{5}{2}R-\frac{3}{2}R=R
\]
\( \textbf{Substitution:} \)
\[
\Delta Q=(3.0)(8.3)(80)
\]
\( \textbf{Calculation:} \)
\[
\Delta Q=1992\,\text{J}
\]
\( \textbf{Final answer:} \) The diatomic gas requires about \(1.99\times10^3\,\text{J}\) more heat at constant volume.
316. An ideal gas is in a vessel of volume \(V\) at temperature \(T\). The molecule count is doubled and the temperature is changed to \(\frac{T}{2}\), while the volume remains \(V\). The pressure becomes
ⓐ. \(\frac{P}{4}\)
ⓑ. \(\frac{P}{2}\)
ⓒ. \(P\)
ⓓ. \(2P\)
Correct Answer: \(P\)
Explanation: \( \textbf{Molecule-scale ideal-gas equation:} \)
\[
PV=Nk_BT
\]
\( \textbf{Initial pressure:} \)
\[
P_1=\frac{N_1k_BT_1}{V}
\]
\( \textbf{Changed molecule count:} \)
\[
N_2=2N_1
\]
\( \textbf{Changed temperature:} \)
\[
T_2=\frac{T_1}{2}
\]
\( \textbf{Final pressure:} \)
\[
P_2=\frac{N_2k_BT_2}{V}
\]
\( \textbf{Substitution:} \)
\[
P_2=\frac{(2N_1)k_B(T_1/2)}{V}
\]
\( \textbf{Simplification:} \)
\[
P_2=\frac{N_1k_BT_1}{V}=P_1
\]
\( \textbf{Final answer:} \) The pressure remains \(P\), because the doubled molecule count is exactly balanced by halving absolute temperature.
317. A gas of molar mass \(M=20\times10^{-3}\,\text{kg mol}^{-1}\) has density \(0.80\,\text{kg m}^{-3}\) at \(T=500\,\text{K}\). Taking \(R=8.0\,\text{J mol}^{-1}\text{K}^{-1}\), its pressure is
ⓐ. \(8.0\times10^4\,\text{Pa}\)
ⓑ. \(1.6\times10^5\,\text{Pa}\)
ⓒ. \(2.0\times10^5\,\text{Pa}\)
ⓓ. \(3.2\times10^5\,\text{Pa}\)
Correct Answer: \(1.6\times10^5\,\text{Pa}\)
Explanation: \( \textbf{Given density:} \) \(\rho=0.80\,\text{kg m}^{-3}\).
\( \textbf{Molar mass:} \) \(M=20\times10^{-3}\,\text{kg mol}^{-1}\).
\( \textbf{Temperature:} \) \(T=500\,\text{K}\).
\( \textbf{Gas constant:} \) \(R=8.0\,\text{J mol}^{-1}\text{K}^{-1}\).
\( \textbf{Density relation:} \)
\[
\rho=\frac{PM}{RT}
\]
\( \textbf{Rearrange for pressure:} \)
\[
P=\frac{\rho RT}{M}
\]
\( \textbf{Substitution:} \)
\[
P=\frac{(0.80)(8.0)(500)}{20\times10^{-3}}
\]
\( \textbf{Numerator:} \)
\[
(0.80)(8.0)(500)=3200
\]
\( \textbf{Division by molar mass:} \)
\[
P=\frac{3200}{0.020}=1.6\times10^5\,\text{Pa}
\]
\( \textbf{Final answer:} \) The pressure is \(1.6\times10^5\,\text{Pa}\).
318. A gas has \(v_{\text{rms}}=500\,\text{m s}^{-1}\) and mean free path \(2.5\times10^{-7}\,\text{m}\). If the temperature is made four times as large while the number density and molecular diameter remain unchanged, the new collision frequency is
ⓐ. \(1.0\times10^9\,\text{s}^{-1}\)
ⓑ. \(2.0\times10^9\,\text{s}^{-1}\)
ⓒ. \(4.0\times10^9\,\text{s}^{-1}\)
ⓓ. \(8.0\times10^9\,\text{s}^{-1}\)
Correct Answer: \(4.0\times10^9\,\text{s}^{-1}\)
Explanation: \( \textbf{Initial rms speed:} \) \(v_1=500\,\text{m s}^{-1}\).
\( \textbf{Mean free path:} \) \(\lambda=2.5\times10^{-7}\,\text{m}\).
\( \textbf{Temperature change:} \)
\[
T_2=4T_1
\]
\( \textbf{Rms-speed proportionality for same gas:} \)
\[
v_{\text{rms}}\propto\sqrt{T}
\]
\( \textbf{New speed:} \)
\[
v_2=v_1\sqrt{4}=2v_1=1000\,\text{m s}^{-1}
\]
\( \textbf{Why } \lambda \textbf{ is unchanged:} \) Number density and molecular diameter are unchanged, so \(\lambda=\frac{1}{\sqrt{2}\pi d^2n_v}\) is unchanged.
\( \textbf{Collision frequency:} \)
\[
z=\frac{v_{\text{rms}}}{\lambda}
\]
\( \textbf{Substitution:} \)
\[
z_2=\frac{1000}{2.5\times10^{-7}}
\]
\( \textbf{Calculation:} \)
\[
z_2=4.0\times10^9\,\text{s}^{-1}
\]
\( \textbf{Final answer:} \) The new collision frequency is \(4.0\times10^9\,\text{s}^{-1}\).
319. A mixture contains \(2.0\,\text{mol}\) of a monatomic ideal gas and \(1.0\,\text{mol}\) of a diatomic ideal gas at ordinary temperature, all at the same \(T=300\,\text{K}\). The total internal energy of the mixture is closest to \(R=8.3\,\text{J mol}^{-1}\text{K}^{-1}\)
ⓐ. \(7.5\times10^3\,\text{J}\)
ⓑ. \(1.37\times10^4\,\text{J}\)
ⓒ. \(1.87\times10^4\,\text{J}\)
ⓓ. \(2.49\times10^4\,\text{J}\)
Correct Answer: \(1.37\times10^4\,\text{J}\)
Explanation: \( \textbf{Monatomic amount:} \) \(n_m=2.0\,\text{mol}\).
\( \textbf{Diatomic amount:} \) \(n_d=1.0\,\text{mol}\).
\( \textbf{Temperature:} \) \(T=300\,\text{K}\).
\( \textbf{Monatomic internal energy:} \)
\[
U_m=\frac{3}{2}n_mRT
\]
\( \textbf{Diatomic internal energy at ordinary temperature:} \)
\[
U_d=\frac{5}{2}n_dRT
\]
\( \textbf{Total internal energy:} \)
\[
U=U_m+U_d
\]
\( \textbf{Substitution:} \)
\[
U=\frac{3}{2}(2.0)RT+\frac{5}{2}(1.0)RT
\]
\( \textbf{Coefficient total:} \)
\[
\frac{3}{2}(2.0)+\frac{5}{2}(1.0)=3.0+2.5=5.5
\]
\( \textbf{Numerical calculation:} \)
\[
U=5.5(8.3)(300)
\]
\( \textbf{Result:} \)
\[
U=13695\,\text{J}\approx1.37\times10^4\,\text{J}
\]
\( \textbf{Final answer:} \) The total internal energy is closest to \(1.37\times10^4\,\text{J}\).
320. A gas sample has pressure \(1.0\times10^5\,\text{Pa}\), volume \(0.030\,\text{m}^3\), and \(N=7.5\times10^{23}\) molecules. Taking \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\), its temperature is closest to
ⓐ. \(145\,\text{K}\)
ⓑ. \(290\,\text{K}\)
ⓒ. \(435\,\text{K}\)
ⓓ. \(580\,\text{K}\)
Correct Answer: \(290\,\text{K}\)
Explanation: \( \textbf{Pressure:} \) \(P=1.0\times10^5\,\text{Pa}\).
\( \textbf{Volume:} \) \(V=0.030\,\text{m}^3\).
\( \textbf{Molecule count:} \) \(N=7.5\times10^{23}\).
\( \textbf{Boltzmann constant:} \) \(k_B=1.38\times10^{-23}\,\text{J K}^{-1}\).
\( \textbf{Molecule-scale ideal-gas equation:} \)
\[
PV=Nk_BT
\]
\( \textbf{Rearrange for temperature:} \)
\[
T=\frac{PV}{Nk_B}
\]
\( \textbf{Numerator:} \)
\[
PV=(1.0\times10^5)(0.030)=3.0\times10^3\,\text{J}
\]
\( \textbf{Denominator:} \)
\[
Nk_B=(7.5\times10^{23})(1.38\times10^{-23})=10.35\,\text{J K}^{-1}
\]
\( \textbf{Calculation:} \)
\[
T=\frac{3000}{10.35}\approx290\,\text{K}
\]
\( \textbf{Final answer:} \) The temperature is closest to \(290\,\text{K}\).