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Question: Calculate the molar heat of vaporization of a fluid whose vapor pressure doubles when the temperatur...

Calculate the molar heat of vaporization of a fluid whose vapor pressure doubles when the temperature is raised from 75{75^ \circ }to 100C{100^ \circ }C .

Explanation

Solution

The molar heat of vaporization is the energy needed to vaporize one mole of a liquid. The units are usually kilojoules per mole. We solve this question by using the clausius-clapeyron equation. The Clausius-Clapeyron equation is an equation that displays the exponential relationship between vapor pressure and temperature. It is important because it gives a linear relationship between the natural logarithm of the vapor pressure and the inverse of the temperature.

Complete Step By Step Answer:
The variation of vapor pressure pi{p_i} with the desired boiling temperature Ti{T_i} is given by the clausius-clapeyron equation:
Where, ΔHvap\Delta \overline {{H_{vap}}} is the molar enthalpy of vaporization and R=8.314472Jmol.KR = 8.314472\dfrac{J}{{mol.K}} is the universal gas constant.
Since we want to see the vapor pressure double due to raising the temperature from 75{75^ \circ }to 100C{100^ \circ }C . Let:
P2=2P1\Rightarrow {P_2} = 2{P_1}
T1=75+273.15K=348.15K\Rightarrow {T_1} = 75 + 273.15K = 348.15K
T2=100+273.15K=373.15K\Rightarrow {T_2} = 100 + 273.15K = 373.15K
Therefore:
ln(2)=ΔHvap8.314jmol.K[1373.15k1348.15k]\Rightarrow \ln (2) = - \dfrac{{\Delta \overline {{H_{vap}}} }}{{8.314\dfrac{j}{{mol.K}}}}\left[ {\dfrac{1}{{373.15k}} - \dfrac{1}{{348.15k}}} \right]
2.315×105×ΔHvapmolJ2.315 \times {10^{ - 5}} \times \Delta \overline {{H_{vap}}} \dfrac{{mol}}{J}
As a result:
ΔHvap=ln22.315×105Jmol\Rightarrow \Delta \overline {{H_{vap}}} = \dfrac{{\ln 2}}{{2.315 \times {{10}^{ - 5}}}}\dfrac{J}{{mol}}
29946Jmol\Rightarrow 29946\dfrac{J}{{mol}}
29.95kJmol\Rightarrow 29.95\dfrac{{kJ}}{{mol}} .

Additional Information:
Limitations of clausius-clapeyron equation:
-One cannot get something for nothing, because of the conservation of matter and energy.
-One cannot return to the same energy state, because entropy, or disorder, always increases.
-Absolute zero is unattainable because no perfectly pure substance exists.

Note:
Remember this kind of fluid would have moderate dipole-dipole forces, as water has ΔHvap=40.67kJmol\Delta \overline {{H_{vap}}} = 40.67\dfrac{{kJ}}{{mol}} at its boiling point. Dipole -dipole interactions occur when the partial charges formed within one molecule are attracted to an opposite partial charge in a nearby molecule. Polar molecules align so that the positive end of one molecule interacts with the negative end of another molecule.