Question

Calculate the molar heat of vaporization of a fluid whose vapor pressure doubles when the temperature is raised from 75°C to 100°C ?

Answer 1

`DeltabarH_(vap) ~~ "29.95 kJ/mol"`

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The variation of vapor pressure `P_i` with the desired boiling temperature `T_i` is given by the Clausius-Clapeyron equation:

`ln (P_2/P_1) = -(DeltabarH_(vap))/R[1/T_2 - 1/T_1]`

where `DeltabarH_(vap)` is the molar enthalpy of vaporization and `R = "8.314472 J/mol"cdot"K"` is the universal gas constant.

Since we want to see the vapor pressure double due to raising the temperature from `75^@ "C"` and `100^@ "C"`, let:

• `P_2 = 2P_1`
• `T_1 = 75 + "273.15 K" = "348.15 K"`
• `T_2 = 100 + "273.15 K" = "373.15 K"`

Therefore:

`ln(2) = -(DeltabarH_(vap))/("8.314 J/mol"cdotcancel"K")[1/(373.15 cancel"K") - 1/(348.15 cancel"K")]`

`= 2.315 xx 10^(-5)cdotDeltabarH_(vap) " ""mol"/"J"`

As a result:

`color(blue)(DeltabarH_(vap)) = (ln2)/(2.315 xx 10^(-5)) "J"/"mol"`

`=` `"29946 J/mol"`

`=` `color(blue)("29.95 kJ/mol")`

This kind of fluid would have moderate dipole-dipole forces, as water has `DeltabarH_(vap) = "40.67 kJ/mol"` at its boiling point.