For the following given reaction, the standard equilibrium K p value has to be calculated at 25 o C . I 2 ( g ) + C l 2 ( g ) ⇌ 2 I C l ( g ) Concept introduction: Free energy change ΔG : change in the free energy takes place while reactants convert to product where both are in standard state. It depends on the equilibrium constant K ΔG = ΔG o + RT ln ( K ) ΔG o = ΔH o − TΔS o Where, T is the temperature ΔG is the free energy ΔG o , ΔH o and ΔS o is standard free energy, enthalpy and entropy values. Free energy (Gibbs free energy) is the term that is used to explain the total energy content in a thermodynamic system that can be converted into work. The free energy is represented by the letter G . All spontaneous process is associated with the decrease of free energy in the system. The standard free energy change (ΔG ° rxn ) is the difference in free energy of the reactants and products in their standard state. ΔG ° rxn = ∑ mΔG f ° (Products)- ∑ nΔG f ° (Reactants) Where, nΔG f ° ( Reactants ) is the standard entropy of the reactants mΔG f ° ( products ) is the standard free energy of the products
For the following given reaction, the standard equilibrium K p value has to be calculated at 25 o C . I 2 ( g ) + C l 2 ( g ) ⇌ 2 I C l ( g ) Concept introduction: Free energy change ΔG : change in the free energy takes place while reactants convert to product where both are in standard state. It depends on the equilibrium constant K ΔG = ΔG o + RT ln ( K ) ΔG o = ΔH o − TΔS o Where, T is the temperature ΔG is the free energy ΔG o , ΔH o and ΔS o is standard free energy, enthalpy and entropy values. Free energy (Gibbs free energy) is the term that is used to explain the total energy content in a thermodynamic system that can be converted into work. The free energy is represented by the letter G . All spontaneous process is associated with the decrease of free energy in the system. The standard free energy change (ΔG ° rxn ) is the difference in free energy of the reactants and products in their standard state. ΔG ° rxn = ∑ mΔG f ° (Products)- ∑ nΔG f ° (Reactants) Where, nΔG f ° ( Reactants ) is the standard entropy of the reactants mΔG f ° ( products ) is the standard free energy of the products
For the following given reaction, the standard equilibrium Kp value has to be calculated at 25oC.
I2(g)+Cl2(g)⇌2ICl(g)
Concept introduction:
Free energy changeΔG: change in the free energy takes place while reactants convert to product where both are in standard state. It depends on the equilibrium constant K
ΔG =ΔGo+RTln(K)ΔGo=ΔHo−TΔSo
Where,
T is the temperature
ΔG is the free energy
ΔGo, ΔHo and ΔSo is standard free energy, enthalpy and entropy values.
Free energy (Gibbs free energy) is the term that is used to explain the total energy content in a thermodynamic system that can be converted into work. The free energy is represented by the letter G. All spontaneous process is associated with the decrease of free energy in the system. The standard free energy change (ΔG°rxn) is the difference in free energy of the reactants and products in their standard state.
ΔG°rxn=∑mΔGf°(Products)-∑nΔGf°(Reactants)
Where,
nΔGf°(Reactants) is the standard entropy of the reactants
mΔGf°(products) is the standard free energy of the products
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The Laws of Thermodynamics, Entropy, and Gibbs Free Energy; Author: Professor Dave Explains;https://www.youtube.com/watch?v=8N1BxHgsoOw;License: Standard YouTube License, CC-BY