A tank of volume `0.2 m^3` contains helium gas at a temperature of `300 K` and pressure `1.0 xx 10^5 N m^(-2)`. Find the amount of heat required to raise the temperature to `400 K`. The molar heat capacity of helium at constant volume is `3.0 cal K^(-1 ) mol^(-1)`. Neglact any expansion in the volume of tank.

A tank of volume `0.2 m^3` contains helium gas at a temperature of `30

1.	A tank of volume `0.2 m^3` contains helium gas at a temperature of `300 K` and pressure `1.0 xx 10^5 N m^(-2)`. Find the amount of heat required to raise the temperature to `400 K`. The molar heat capacity of helium at constant volume is `3.0 cal K^(-1 ) mol^(-1)`. Neglact any expansion in the volume of tank.
Answer» The amount of the gas in moles is `n=p^V/RT` `=(1.0 xx 10^5 N m ^(-2)) (0.2 m ^3 )/(8.31 J K^(-1) mol^(-1)) (300 K )= 8.0mol`. The amount of heat required is `DeltaQ = nC_v Delta T` `=(8.0 mol) (3.0 cal mol^(-1) K^(-1)) (100k ) 2400 cal`.

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