25.9 kJ/mol. (3 sig. fig. as in the heat capacity.)
The process:
[tex]\text{KNO}_3\;(s) \to \text{KNO}_3\;(aq)[/tex].
How many moles of this process?
Relative atomic mass from a modern periodic table:
Molar mass of [tex]\text{KNO}_3[/tex]:
[tex]M(\text{KNO}_3) = 39.098 + 14.007 + 3\times 15.999 = 101.102\;\text{g}\cdot\text{mol}^{-1}[/tex].
Number of moles of the process = Number of moles of [tex]\text{KNO}_3[/tex] dissolved:
[tex]\displaystyle n = \frac{m}{M} = \frac{21.45}{101.102} = 0.212162\;\text{mol}[/tex].
What's the enthalpy change of this process?
[tex]Q = C\cdot \Delta T = 0.505 \times (25.00 - 14.14) = 5.4843\;\text{kJ}[/tex] for [tex]0.212162\;\text{mol}[/tex]. By convention, the enthalpy change [tex]\Delta H[/tex] measures the energy change for each mole of a process.
[tex]\displaystyle \Delta H = \frac{Q}{n} = \frac{5.4843\text{kJ}}{0.212162\;\text{mol}} = 25.8\;\text{kJ}\cdot\text{mol}^{-1}[/tex].
The heat capacity is the least accurate number in these calculation. It comes with three significant figures. As a result, round the final result to three significant figures. However, make sure you keep at least one additional figure to minimize the risk of rounding errors during the calculation.
