Answer:
Kc = [ICl]² / [Cl₂] . [I₂] →2.32² / 1.84 . 0.94 = 3.11
Explanation:
Let's propose the equilibrium reaction:
Cl₂(g) + I₂(g) ⇄ 2ICl(g)
Initial 3 m 2.10m -
React x x 2x
X amount has reacted of chlorine and iodine, so by stoichiometry, we made 2X of ICl.
As we have this molar concentration we can determine the x → 2x = 2.32. Then x = 2.32/ 2 = 1.16
Eq (3 m - 1.16) (2.10-1.16) 2.32
Molar concentrations in the equilibrium are: [Cl₂]= 1.84M, [I₂] = 0.94M
Let's make the expression for Kc:
Kc = [ICl]² / [Cl₂] . [I₂] →2.32² / 1.84 . 0.94 = 3.11
Answer:
The equilibrium constant is 3.11
Explanation:
Step 1: Data given
Number of moles Cl2 = 3.00 moles
Number of moles I2 = 2.10 moles
Volume = 1.00L
Temperature = 350 °C
Concentration of ICl at the equilibrium = 2.32 M
Step 2: The balanced equation
Cl2 + I2 → 2ICl
Step 3: Calculate initial concentrations
[Cl2] = 3.00 moles / 1L = 3.00 M
[I2] = 2.10 moles / 1L = 2.10 M
[ICl]= 0M
Step 4: Calculate concentration at equilibrium
[Cl2] = 3.00 - X M
[I2] = 2.10 - X M
[ICl]= 2X = 2.32 M
X = 2.32 / 2 = 1.16 M
[Cl2] = 3.00 - 1.16 M = 1.84 M
[I2] = 2.10 - 1.16 M = 0.94 M
[ICl]= 2X = 2.32 M
Step 5: Calculate Kc
Kc = [ICl]²/[Cl2][I2]
Kc = 2.32²/(1.84*0.94)
Kc = 3.11
The equilibrium constant is 3.11
