Answer:
ΔHrxn = - 34,653 J/mol Cu(OH)₂
0.225 mol Cu(OH)₂
Explanation:
The reaction in this question is
CuSO₄ + 2 KOH ⇒ Cu(OH)₂ + K₂SO₄ ( double displacement )
Now notice we are told the temperature in both the calorimeter and solution increases from 25.2 ºC to 31.3 ºC after mixing. Thus we have an exothermic reaction and to calculate its heat of reaction we need to compute the heat absorbed by the calorimeter and the solution keeping in mind that the solution is dilute enough to assume the heat capacity of the solution and its density are the same as that of water.
q solution = m x c x ΔT
where m is the mass of solution, c is the specific heat of water, and ΔT is the change in temperature for the reaction.
We know the volume of mixing and the density of water so we can calculate m:
vol mix = 150.0 mL + 150.0 mL = 300.0 mL
m = 300.0 mL x 1 g/ mL
T₀ = 25.2 ºC + 273 = 298.2 K
T₁ = 31.3 ºC + 273 = 304.3 K
ΔT = 304.3 K - 297.2 K = 6.1 K
q solution = 300.0 g x 4.18 J / g·K x 6.1 K = 7649.4 J
q calorimeter = C calorimeter x ΔT = 24.2 J/K x 6.1 K = 147.6 K
q total = 7649.4 J + 147.6 K = 7797 J
Now we have the total heat of the reaction but we are asked the change in enthalpy per mole of Cu(OH)₂.
To determine the mol Cu(OH)₂ formed we need to perform a calculation based on the stoichiometry of the reaction.
To do that first calculate the number of moles of reactants, check if there is a limiting reagent and finally calculate the number of moles of Cu(OH)₂.
mol reactants:
Molarity = mol/L solution ⇒ mol = M x L
mol CuSO₄ = 1.50 mol/L x (150 mL/1000 mL/L) = 0.225 mol
mol KOH = 3.0 mol/L x (150 mL/1000 mL/L) = 0.45 mol
We know from the coefficients of the balanced equation that 1 mol of CuSO₄ will react with 2 mol KOH to produce 1 mol Cu(OH)₂ , thus 0.225 mol CuSO₄ will react with 0.45 mol KOH to produce 0.225 mol Cu(OH)₂.
Now we can calculate ΔHrxn:
= - 7797 J / 0.225 mol Cu(OH)₂ = -34,653J/mol Cu(OH)₂
( Do not forget the negative sign in the change in enthalpy since we are dealing with an exothermic reaction )
