Final answer:
To calculate the enthalpy of dissolution of BaBr2(s) in kJ/mol, we can use the equation q = -mCΔT. By substituting the given values and calculating the heat transferred, we then divide by the moles of BaBr2(s) dissolved to find the enthalpy of dissolution. The enthalpy of dissolution of BaBr2(s) is approximately -18.5 kJ/mol.
Step-by-step explanation:
To calculate the enthalpy of dissolution of BaBr2(s) in kJ/mol, we need to use the equation:
q = -mCΔT
Where q is the heat transferred, m is the mass of the solution, C is the specific heat of the solution, and ΔT is the change in temperature of the solution.
First, we need to calculate the mass of the solution. This is done by adding the mass of the BaBr2(s) to the mass of water:
mass of solution = mass of BaBr2(s) + mass of water
mass of solution = 24.22 g + 118.20 g = 142.42 g
Next, we calculate the heat transferred:
q = -mCΔT
q = -(142.42 g)(4.18 J/g °C)(28.18 °C - 24.85 °C)
q = -1987.87 J
Finally, we convert the heat transferred to kJ/mol by dividing by the moles of BaBr2(s) dissolved:
moles of BaBr2(s) = mass of BaBr2(s) / molar mass of BaBr2
moles of BaBr2(s) = 24.22 g / (137.33 g/mol + 2(79.90 g/mol))
moles of BaBr2(s) = 0.1072 mol
enthalpy of dissolution = q / moles of BaBr2(s)
enthalpy of dissolution = -1987.87 J / 0.1072 mol = -18514.92 J/mol
Therefore, the enthalpy of dissolution of BaBr2(s) is -18514.92 J/mol or -18.5 kJ/mol.