Answer:
The total heat associated is -30,520.3 J.
Explanation:
Moles of ethanol = 0.499 moles
Molar mass of ethanol = 46 g/mol
Mass = Moles × Molar mass = 0.499 moles × 46 g/mol = 22.954 g
m is the mass of ethanol = 22.954 g
Q₁ is heat involved in the conversion of 22.954 g ethanol gas at 301°C to ethanol gas at 78.5°C
Thus, Q₁ = m × c × ΔT
Where,
c = The specific heat of the gas = 1.43 J/g°C
ΔT = Final temperature - Initial temperature = 78.5 - 301°C
= - 222.5 °C
Applying the values in the above equation as:-
![Q_1 = 22.954 g\times 1.43 J/g^0C\times (-222.5^oC) = -7303.3J](https://tex.z-dn.net/?f=Q_1%20%3D%2022.954%20g%5Ctimes%201.43%20J%2Fg%5E0C%5Ctimes%20%28-222.5%5EoC%29%20%3D%20-7303.3J)
Q₂ is the enthalpy of condensation from gas to liquid for the given mass of ethanol .
Thus, Q₂ = moles×ΔH condensation
Given that:- ΔH vaporization = 40.5 kJ/mol
Enthalpy of condensation of gaseous ethanol to liquid ethanol = - 40.5 kJ/mol
Considering, 1 kJ = 1000 J
So,
ΔH condensation = - 40.5 ×1000 J/mol = - 40500 J/mol
Thus, Q₂ = 0.499 moles × (- 40500 J/mol) = -20209.5 J
Q₃ is heat involved in the conversion of 22.954 g gaseous ethanol at 78.5°C to ethanol liquid at 25.0°C.
Thus, Q₃ = m × C ×ΔT
Where,
C = The specific heat of the liquid = 2.45 J/g°C
ΔT = Final temperature - Initial temperature = 25.0 - 78.5 °C
= - 53.5 °C
Applying the values in the above equation as:-
![Q_3 = 22.954 g\times 2.45 J/g^0C\times (-53.5 ^0C)=-3007.5 J](https://tex.z-dn.net/?f=Q_3%20%3D%2022.954%20g%5Ctimes%202.45%20J%2Fg%5E0C%5Ctimes%20%28-53.5%20%5E0C%29%3D-3007.5%20J)
Applying the values as:
Total heat = ![Q_1+Q_2+Q_3](https://tex.z-dn.net/?f=Q_1%2BQ_2%2BQ_3)
= -7303.3 J - 20209.5 J - 3007.5 J
= -30,520.3 J
The total heat associated is -30,520.3 J.