Answer:
8
Explanation:
Here we're dealing with the root mean square velocity of gases. We'll provide the formula in order to calculate the root mean square velocity of a gas:
[tex]v_{rms}=\sqrt{\frac{3RT}{M}}[/tex]
Here:
[tex]R = 8.314 \frac{J}{K mol}[/tex] is the ideal gas law constant;
[tex]T[/tex] is the absolute temperature in K;
[tex]M[/tex] is the molar mass of a compound in kg/mol.
We know that the gas from the red container is 4 times faster, as it takes 4 times as long for the yellow container to leak out, this means:
[tex]\frac{v_{rms, red}}{v_{rms, yellow}} = 4[/tex]
We also know that the temperature of the red container is twice as large:
[tex]\frac{T_{red}}{T_{yellow}} = 2[/tex]
Write the ratio of the velocities and substitute the variables:
[tex]\frac{v_{rms, red}}{v_{rms, yellow}}=\frac{\sqrt{\frac{3RT_{red}}{M_{red}}}}{\sqrt{\frac{3RT_{yellow}}{M_{yellow}}}}=4[/tex]
Then:
[tex]\frac{\sqrt{\frac{3RT_{red}}{M_{red}}}}{\sqrt{\frac{3RT_{yellow}}{M_{yellow}}}}=\sqrt{\frac{3RT_{red}}{M_{red}}\cdot \frac{M_{yellow}}{3RT_{yellow}}}=\sqrt{\frac{T_{red}}{T_{yellow}}\cdot \frac{M_{yellow}}{M_{red}}}=4[/tex]
From here:
[tex]16 = \frac{T_{red}}{T_{yellow}}\cdot \frac{M_{yellow}}{M_{red}}[/tex]
Then:
[tex]\frac{M_{yellow}}{M_{red}} = \frac{16}{\frac{T_{red}}{T_{yellow}}} = \frac{16}{2} = 8[/tex]
