For one mole, molecular volume is $N_A\frac43\pi r^3$, with $r=1.5\times10^{-10}\,\text{m}$. Thus molecular volume $=6.02\times10^{23}\times\frac43\pi(1.5\times10^{-10})^3=8.51\times10^{-6}\,\text{m}^3$. Actual molar volume at STP is $22.4\,\text{L}=2.24\times10^{-2}\,\text{m}^3$. Fraction $=8.51\times10^{-6}/2.24\times10^{-2}=3.8\times10^{-4}$.
$3.8\times10^{-4}$ approximately.
For one mole of an ideal gas, $V=RT/P$. At STP, $T=273.15\,\text{K}$ and $P=1.013\times10^5\,\text{Pa}$. Hence $V=8.31(273.15)/(1.013\times10^5)=2.24\times10^{-2}\,\text{m}^3=22.4\,\text{L}$.
$22.4\,\text{L}$.
Use absolute pressures: initially $P_1=16\,\text{atm}$ and finally $P_2=12\,\text{atm}$. With $V=0.030\,\text{m}^3$, $T_1=300\,\text{K}$ and $T_2=290\,\text{K}$, $n_1=P_1V/(RT_1)=19.50\,\text{mol}$ and $n_2=P_2V/(RT_2)=15.13\,\text{mol}$. Moles removed $=4.37$, so mass removed $=4.37(0.032)=0.140\,\text{kg}$.
$0.14\,\text{kg}$ approximately.
At the bottom, $P_1=P_0+\rho gh=1.013\times10^5+1000(9.8)(40)=4.93\times10^5\,\text{Pa}$. At the surface, $P_2=P_0=1.013\times10^5\,\text{Pa}$. Temperatures are $T_1=285\,\text{K}$ and $T_2=308\,\text{K}$. From $PV/T=\text{constant}$, $V_2=V_1(P_1/P_2)(T_2/T_1)=1.0(4.87)(1.08)=5.26\,\text{cm}^3$.
$5.3\,\text{cm}^3$ approximately.
Using $PV=Nk_BT$, $N=PV/(k_BT)=\frac{(1.013\times10^5)(25.0)}{(1.38\times10^{-23})(300)}=6.1\times10^{26}$ molecules.
$6.1\times10^{26}$ molecules.
For a monatomic atom, average translational thermal energy is $\frac32k_BT$. At $300\,\text{K}$, this is $1.5(1.38\times10^{-23})(300)=6.2\times10^{-21}\,\text{J}$. At $6000\,\text{K}$ it is $1.24\times10^{-19}\,\text{J}$. At $10^7\,\text{K}$ it is $2.07\times10^{-16}\,\text{J}$.
(i) $6.2\times10^{-21}\,\text{J}$. (ii) $1.24\times10^{-19}\,\text{J}$. (iii) $2.07\times10^{-16}\,\text{J}$.
Equal $P$, $V$ and $T$ imply equal $N$ from $PV=Nk_BT$. The rms speed is $v_{rms}=\sqrt{3k_BT/m}$, so at the same temperature it is larger for smaller molecular mass. Neon is lighter than chlorine and uranium hexafluoride, so neon has the largest rms speed.
Yes, they contain equal numbers of molecules. No, their rms speeds are not the same; $v_{rms}$ is largest for neon.
Equal rms speeds require $T_{Ar}/M_{Ar}=T_{He}/M_{He}$. The helium temperature is $253\,\text{K}$. Thus $T_{Ar}=253(39.9/4.0)=2.53\times10^3\,\text{K}$.
$2.5\times10^3\,\text{K}$ approximately.
At $P=2.0\,\text{atm}$ and $T=290\,\text{K}$, number density $n=P/(k_BT)=5.06\times10^{25}\,\text{m}^{-3}$. Molecular diameter $d=2.0\times10^{-10}\,\text{m}$. Mean free path $l=1/(\sqrt2\pi d^2n)=1.11\times10^{-7}\,\text{m}$. The rms speed is $v=\sqrt{3RT/M}=\sqrt{3(8.31)(290)/0.028}=508\,\text{m s}^{-1}$. Collision frequency $=v/l=4.6\times10^9\,\text{s}^{-1}$ and free time $=l/v=2.2\times10^{-10}\,\text{s}$. A collision time of order $d/v=4\times10^{-13}\,\text{s}$ is far smaller.
Mean free path $\approx1.1\times10^{-7}\,\text{m}$; collision frequency $\approx4.6\times10^9\,\text{s}^{-1}$. Collision duration is about $4\times10^{-13}\,\text{s}$, much smaller than the free-flight time $2.2\times10^{-10}\,\text{s}$.