State Le Chatelier's principle - Leaving Cert Chemistry - Question a - 2003

The expression for the equilibrium constant, Kc, for the reaction

$H₂(g) + I₂(g) ⇌ 2HI(g)$

is given by:

K_c = rac{[HI]^2}{[H₂][I₂]}

where [HI], [H₂], and [I₂] are the molar concentrations of hydrogen iodide, hydrogen, and iodine at equilibrium, respectively.

Let the initial concentration of hydrogen iodide, [HI], be calculated as follows:

Given that the volume of the vessel is not specified, we can use moles directly. Initially, we have:

• 0 moles of H₂
• 0 moles of I₂
• 2 moles of HI

Using the equilibrium expression, we can define: Let x be the amount of HI that dissociates:

The change in moles at equilibrium will be:

• H₂: 0 + x
• I₂: 0 + x
• HI: 2 - 2x

From the equilibrium constant expression:

K_c = rac{(2 - 2x)^2}{(x)(x)}

Substituting in the value of Kc:

50 = rac{(2 - 2x)^2}{x^2}

Rearranging gives the equation:
$50x^2 = (2 - 2x)^2$

Now, expanding and solving this quadratic equation will provide the value of x. After obtaining x, the final concentration of HI can be calculated as:

$[HI] = 2 - 2x$

Calculating for Kc = 50 results in:

• When x is solved, you will find, for example, that x = 0.44, leading to: $[HI] = 2 - 2(0.44) = 1.12 ext{ moles (for example, apply your final x)}$.