![Equilibrium_Constants_From_Other_Constants (1) Equilibrium_Constants_From_Other_Constants (1)](https://i0.wp.com/www.chem.purdue.edu/../../common/BarcelonaBanner.gif)
Calculating K for a Reaction
Using Known K's for Other Reactions
- K for a Reversed Reaction
- Reaction Coefficients Multiplied by a Number
- Adding Two or More Equations
- Calculations Incorporating Two or More of These AlgebraicManipulations
The equilibrium expression written for a reaction written inthe reverse direction is the reciprocal of the one for the forward reaction.
K' is the constant for the reverse reaction and K is that of the forwardreaction.
Example: What is the value of the equilibrium constantfor the reaction 2 NO2(g)N2O4(g)at 100o C?
N2O4(g)2 NO2(g) Kc = 0.212 @ 100oC?
The desired reaction is the reverse of the reaction for which the Kc is known. The equilibrium expression is the reciprocal of thatgiven.
K'c = 1/Kc = 1/0.212 = 4.72
Top
ReactionCoefficients Multiplied by a Number
If the coefficients in a balanced equation are multiplied by a factor,n, the equilibrium expression is raised to the nth power.
K' is the constant for the reaction multiplied byn and K is the constant of the original reaction.
Example: What is the value of the equilibrium constantfor the reaction, 2 I2(g) + 2 Cl2(g) 4ICl(g)?
½ I2(g) + ½ Cl2 (g) ICl(g)Kc = 4.54 x 102 @ 25oC?
The desired reaction has been multiplied by 4. The value of theequilibrium constant will be the 4th power of the given Kc.
K'c = Kc4 = (4.54 x 102)4= 4.25 x 1010
Top
If two or more reactions are added to give another, the equilibrium constant for the reaction is the product of the equilibrium constants of the equations added.
K' = K1 x K2 . . .
K1 , K2, etc. represent the equilibrium constantsfor reactions being added together, and K' represents the equilibrium constantfor the desired reaction.
Example: Calculate the value of Kc for the reaction:2 NO(g) + Br2(g)2 NOBr (g) using the following information.
![Equilibrium_Constants_From_Other_Constants (7) Equilibrium_Constants_From_Other_Constants (7)](https://i0.wp.com/www.chem.purdue.edu/EquilibriumArt/Equilibriumarrows.gif)
N2(g) + Br2(g) + O2(g)
![Equilibrium_Constants_From_Other_Constants (8) Equilibrium_Constants_From_Other_Constants (8)](https://i0.wp.com/www.chem.purdue.edu/EquilibriumArt/Equilibriumarrows.gif)
The two equations can be added to yield the desiredequation. The value of Kc for the reaction will be the productof the other two.
K'c = Kc1 x Kc2 = (1 x 1030)(1x 10-27) = 2 x 103
Top
CalculationsIncorporating Two or More of These Algebraic Manipulations
It is possible to combine more than one of these manipulations.
Example: Calculate the value of Kc forthe reaction: 2 N2O(g) + 3 O2(g)2 N2O4(g),using the following information.
Equation | Equilibrium Constant |
2 N2 (g) + O2(g)![]() | Kc = 1.2 x 10-35 |
N2O4(g)![]() | Kc = 4.6 x 10-3 |
½ N2(g) + O2(g)![]() | Kc = 4.1 x 10-9 |
![Equilibrium_Constants_From_Other_Constants (13) Equilibrium_Constants_From_Other_Constants (13)](https://i0.wp.com/www.chem.purdue.edu/EquilibriumArt/KfromotherKs.gif)
- Write the first equation backwards. The K for this reaction willbe the recipricol of the forward reaction.
![]() | 8.3 x 1034 |
- Write the second equation backwards and multiply the coefficients by 2.The K for this reaction will be the recipricol of the forward reaction squared.
![]() | 4.7 x 104 |
- Use the third equation in the forward direction but multiplied by 4.The K for this reaction will be the K of the given reaction raised to thefourth power.
![]() | 2.8 x 10-34 |
- Check to see that the three equations yield the desired equation when addedtogether. The equilibrium constant for the desired equation willbe the product of the constants for the three equations combined.