Chem 2 - Gibbs Free Energy and Spontaneous Reactions VI
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Chem 2 - Gibbs Free Energy and Spontaneous Reactions VI
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Chem 2 - Gibbs Free Energy and Spontaneous Reactions VI
- 1. Gibbs Free Energy and Spontaneous Reactions (Pt 6) By Shawn P. Shields, Ph.D. This work is licensed by Shawn P. Shields-Maxwell under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
- 2. Recall: Suniv and Spontaneous Processes The total entropy change of the universe (Suniv) for any spontaneous process is positive. + Suniv Suniv = Ssys + Ssurr
- 3. Suniv and Gibbs Free Energy (G) Calculating Suniv is not convenient. Suniv = Ssys + Ssurr Gibbs proposed a new thermodynamic state function that is derived from three other state functions for the system. Enthalpy, Entropy, and Temperature.
- 4. Gibbs Free Energy (G) G = H TS The Gibbs Free Energy change for a given process is G = H TS (at constant T and P)
- 5. Suniv and Gibbs Free Energy (G) Entropy S is maximized at equilibrium Free energy G is minimized at equilibrium.
- 6. Gibbs Free Energy G Without derivation: TSuniv = Hsys T Ssys TSuniv = G G When G for a given process is negative, the process is spontaneous in the forward direction (as written).
- 7. Predicting Spontaneity and G Negative G means the process is spontaneous (as written; in the forward direction). Positive G means the process is nonspontaneous (as written). However, it is spontaneous in the reverse direction! If G = 0, the reaction is at equilibrium.
- 8. Gibbs Free Energy (G) and Predicting Spontaneous Processes The sign of the Gibbs Free Energy for a given process will depend on the signs of H and S. G = H T S We can predict whether a given process will b spontaneous by analyzing the signs of H and S.
- 9. H, S, and the Sign of G Sign of H Sign of S Sign of G Type of Process negative positive negative spontaneous at all temperatures positive negative positive nonspontaneous at all temperatures positive positive () or (+) Spontaneous if the temperature is high enough negative negative (+) or () Spontaneous if the temperature is low enough G = H T S
- 10. Case 1: H and S Agree (Spontaneous) When H is negative and S is positive, G is always negative. The reaction is spontaneous in the forward direction (any T). G = H T S G = () T (+) G = () (+)(+) G = a negative number (any T) T in K, so always a positive number! Negative term
- 11. Case 2: H and S Agree (Nonspontaneous) H is positive and S is negative, so G is always positive. The reaction is nonspontaneous in the forward direction (any T). Spontaneous in reverse direction. G = H T S G = (+) T () G = (+) (+)() G = a positive number (any T) T in K, so always a positive number! Positive term
- 12. Case 3: H and S Disagree (G “Decides”) H is positive and S is positive, so G is negative or positive depending on the temperature. The reaction is spontaneous in the forward direction if T is high enough. G = H T S G = (+) T (+) G = (+) (+)(+) T in K, so always a positive number! Positive term
- 13. Case 3: H and S Disagree (G “Decides”) The reaction is spontaneous in the forward direction if T is high enough. G = H T S G = (+) T (+) G = (+) (+)(+) G = a positive number (at low T) G = a negative number (at high T) Subtract a large positive term If T is high, subtract a larger number than H
- 14. Case 4: H and S Disagree (G “Decides”) H is negative and S is negative, so G is negative or positive depending on the temperature. The reaction is spontaneous in the forward direction if T is low enough. G = H T S G = () T () G = () (+)() T in K, so always a positive number! negative term
- 15. Case 4: H and S Disagree (G “Decides”) The reaction is spontaneous in the forward direction if T is low enough. G = H T S G = () T () G = () (+)() G = a negative number (at low T) G = a positive number (at high T) a positive term overall If T is low, add a smaller number than H
- 16. Summary: Gibbs Free Energy (G) G = H T S When H is () and S is (+) , G is always (). Spontaneous in the forward direction (any T). H is (+) and S is (), so G is always (+). Nonspontaneous in the forward direction (any T).
- 17. Summary: Gibbs Free Energy (G) G = H T S H is (+) and S is (+), so G is () or (+) depending on the temperature. Spontaneous in the forward direction if T is high enough.
- 18. Summary: Gibbs Free Energy (G) G = H T S H is () and S is (), so G is (+) or () depending on the temperature. Spontaneous in the forward direction if T is low enough.
- 19. Next up… Free Energies of Formation and Calculating Free Energy of Reaction (G) (Pt 7)