Oxygen is filled in a closed metal jar of volume `1.0xx10^(-3)m^(3)` at a pressure of `1.5xx10^(5)Pa.` and temperature `400K`. The jar has a small leak in it. The atmospheric pressure is `1.0xx10^(5)Pa` and the atmospheric temperature is `300K`. Find the mass of the gas that leaks out by time the pressure and the temperature inside the jar equalise with the surrounding.

Oxygen is filled in a closed metal jar of volume `1.0xx10^(-3)m^(3)` a

1.	Oxygen is filled in a closed metal jar of volume `1.0xx10^(-3)m^(3)` at a pressure of `1.5xx10^(5)Pa.` and temperature `400K`. The jar has a small leak in it. The atmospheric pressure is `1.0xx10^(5)Pa` and the atmospheric temperature is `300K`. Find the mass of the gas that leaks out by time the pressure and the temperature inside the jar equalise with the surrounding.
Answer» Given, volume `V =10^(-3) m^(3)`, Pressure `P_(1)=1.5xx10^(5)Pa,P_(2)=10^(5)Pa` Temperature `T_(1)=400 K, T_(2)=300K,` From ideal gas equation, `p_(1)V=n_(1)RT_(1)` `Rightarrow" " n_(1)=p_(1)/(RT_(1))` Similarly,`Similarly" " p_(2)V=n_(2)RT_(2)Rightarrown_(2)=(P_(2)V)/(RT_(2))` `therefore` Number of mole leaked `Delta=n_(1)n_(2)=(P_(1)/T_(1)-P_(2)/T_(2))(V)/(R)=((1.5)/(400)-(1)/(300))xx(10^(5)xx10^(-3))/(8.3)=5.02xx10^(-3)` Mass of gas leaked =`Deltan M_(o)=5.02xx 10^(-3)xx32=0.16 g`

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