| 1. | It shows the relationship between standard free energy change and equilibrium constant.
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| 2. | Since the Gibbs free energy change is negative, aluminium can reduce chromium oxide.
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| 3. | This gives a favourable enthalpy contribution to the Gibbs free energy change for the reaction
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| 4. | The free energy change ( ?G ) for this reaction is 102 kilocalories per mole.
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| 5. | The relationship between free energy change of a system and its interfacial area is expressed in the equation:
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| 6. | The determinant of the degree to which a reaction will proceed to completion is the free energy change.
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| 7. | The acid dissociation constant for an acid is a direct consequence of the underlying Gibbs free energy change for the reaction.
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| 8. | The Gibbs free energy change here is expressed frequently also as electrochemical ion gradient & Delta; & mu; m+
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| 9. | In practice, the efficiency is given by electrical work achieved divided by the Gibbs free energy change of the reaction.
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| 10. | The Ellingham diagram plots the Gibbs free energy change ( ?G ) for each oxidation reaction as a function of temperature.
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