Consider the vaporization of 1g of water at `100^(@)C` at one atmosphere pressure. Compute the work done by the water system in the vaporization and change internal energy of the system.

Consider the vaporization of 1g of water at `100^(@)C` at one atmosphe

1.	Consider the vaporization of 1g of water at `100^(@)C` at one atmosphere pressure. Compute the work done by the water system in the vaporization and change internal energy of the system.
Answer» To change a system of mass m of liquid to vapour heat required is `Q=ml_("vapour")` The process takes place at constant pressure so the work done by the system is the work Where `DeltaV=(V_("vapour")-V_("liquid"))` From first law of thermodynamics `DeltaU=Q-W=mL_(v)-P(V_("vapour"-V_("liquid")))` Latent heat of vaporization of water `L_("vapour")=22.57xx10^(5)J//kg` `Q=(1.00xx10^(-3))(22.57xx10^(5))=2.26xx10^(3)` `because` No. of moles=weight /gram molecular weight `therefore` Moles of water in `1g=(1)/(18)=0.0556` mole `V_("vapour")=(nRT)/(P)=((0.0556)(8.315)(373))/(1.013xx10^(5))=1.70xx10^(-3)m` The density of water is `1.00xx10^(3) kg//m^(3)=1.00 g//cm^(3)` `V_("liquid")=1.00xx10^(-6) m^(3)` Thus the work done by the water system Vaporization is `W=P(V_("vapour")-V_("liquid"))` `=(1.013xx10^(5))(1.70xx10^(-3)-1.00xx10^(-6))=172J` The work done by the system is positive since the volume of the system has increased. From first law, `DeltaU=Q-QrArrDeltaU=2.26xx10^(3)-172=2.09xx10^(3)J`

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Consider the vaporization of 1g of water at `100^(@)C` at one atmosphere pressure. Compute the work done by the water system in the vaporization and change internal energy of the system.

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