For the reaction
\(2A(g)+B(g)→2D(g)\)
\(∆U^Θ= -10.5\ kJ\) and \(∆S^Θ= -44.1\ JK^{-1}\).
Calculate \(∆G^Θ\) for the reaction, and predict whether the reaction may occur spontaneously.
\(2A(g)+B(g)→2D(g)\)
\(∆U^Θ= -10.5\ kJ\) and \(∆S^Θ= -44.1\ JK^{-1}\).
Calculate \(∆G^Θ\) for the reaction, and predict whether the reaction may occur spontaneously.
Solution and Explanation
For the given reaction,
\(2 A(g) + B(g) → 2D(g)\)
∆ng = 2 – (3) = –1 mole
Substituting the value of ∆UΘ in the expression of ∆H:
∆HΘ = ∆UΘ + ∆ngRT
∆Hθ = (–10.5 kJ) – (–1) (8.314 × 10–3 kJ K–1mol–1) (298 K)
∆Hθ = –10.5 kJ – 2.48 kJ
∆Hθ = –12.98 kJ
Substituting the values of ∆HΘ and ∆SΘ in the expression of ∆GΘ:
∆GΘ = ∆HΘ – T∆SΘ
∆GΘ = –12.98 kJ – (298 K) (–44.1 JK–1)
∆GΘ = –12.98 kJ + 13.14 kJ
∆GΘ = + 0.16 kJ
Since ∆GΘ for the reaction is positive, the reaction will not occur spontaneously.
Top Questions on Gibbs energy change and equilibrium
- For a reaction taking place in four different steps, the rate constants follow a relationship \(K-\frac{K_2K_4}{K_1K_3}\). If the energies of activation E1, E2, E3 and E4 are 10 kJ/mol, 30kJ/mol, 40 kJ/mol and 20 kJ/mol respectively, then the overall energy of activation would be :
- CUET (UG) - 2023
- Chemistry
- Gibbs energy change and equilibrium
- (A) (a) Calculate the standard Gibbs energy (\( \Delta G^\circ \)) of the following reaction at 25°C: \[ \text{Au}(s) + \text{Ca}^{2+}(1M) \to \text{Au}^{3+}(1M) + \text{Ca}(s) \] \[ E^\circ_{\text{Au}^{3+}/\text{Au}} = +1.5 \, \text{V}, \quad E^\circ_{\text{Ca}^{2+}/\text{Ca}} = -2.87 \, \text{V} \] Predict whether the reaction will be spontaneous or not at 25°C. [1 F = 96500 C mol\(^{-1}\)]
- CBSE CLASS XII
- Chemistry
- Gibbs energy change and equilibrium
- (A) (a) Calculate the standard Gibbs energy (\( \Delta G^\circ \)) of the following reaction at 25°C: \[ \text{Au}(s) + \text{Ca}^{2+}(1M) \to \text{Au}^{3+}(1M) + \text{Ca}(s) \] \[ E^\circ_{\text{Au}^{3+}/\text{Au}} = +1.5 \, \text{V}, \quad E^\circ_{\text{Ca}^{2+}/\text{Ca}} = -2.87 \, \text{V} \] Predict whether the reaction will be spontaneous or not at 25°C. [1 F = 96500 C mol\(^{-1}\)]
- CBSE CLASS XII
- Chemistry
- Gibbs energy change and equilibrium
- For the reaction, \(2Cl(g)→Cl_2(g)\), what are the signs of \(∆H\) and \(∆S\) ?
- CBSE Class XI
- Chemistry
- Gibbs energy change and equilibrium
- For the reaction at \(298\ K\),
\(2A+B→C\)
\(∆H = 400\ kJ mol^{-1}\) and \(∆S = 0.2\ kJ K^{-1} mol^{-1}\)
At what temperature will the reaction become spontaneous considering \(∆H\) and \(∆S\) to be constant over the temperature range.- CBSE Class XI
- Chemistry
- Gibbs energy change and equilibrium
Questions Asked in CBSE Class XI exam
- Arrange the bonds in order of increasing ionic character in the molecules: LiF, K2O, N2, SO2 and ClF3.
- CBSE Class XI
- Molecular Orbital Theory
- Three reasons why the author’s grandmother was disturbed when he started going to the city school.
- CBSE Class XI
- The Portrait of a lady
Two identical ball bearings in contact with each other and resting on a frictionless table are hit head-on by another ball bearing of the same mass moving initially with a speed V. If the collision is elastic, which of the following (Fig. 5.14) is a possible result after collision ?
- CBSE Class XI
- Collisions
- Why is it necessary to use acetic acid and not sulphuric acid for acidification of sodium extract for testing sulphur by lead acetate test?
- CBSE Class XI
- Organic Chemistry
- Prove that, cos 6 x = 32cos6 x-48cos4 x+18cos2 x -1.
- CBSE Class XI
- Trigonometric Functions of Sum and Difference of Two Angles
Concepts Used:
Gibbs Free Energy
The energy associated with a chemical reaction that can be used to do work.It is the sum of its enthalpy plus the product of the temperature and the entropy (S) of the system.
The Gibbs free energy is the maximum amount of non-expansion work that can be extracted from a thermodynamically closed system. In completely reversible process maximum enthalpy can be obtained.
ΔG=ΔH−TΔS
The Conditions of Equilibrium
If both it’s intensive properties and extensive properties are constant then thermodynamic system is in equilibrium. Extensive properties imply the U, G, A.
