13.4 Equilibrium calculations (Page 6/11)

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Recall that a small K _c means that very little of the reactants form products and a large K _c means that most of the reactants form products. If the system can be arranged so it starts “close” to equilibrium, then if the change ( x ) is small compared to any initial concentrations, it can be neglected. Small is usually defined as resulting in an error of less than 5%. The following two examples demonstrate this.

Approximate solution starting close to equilibrium

What are the concentrations at equilibrium of a 0.15 M solution of HCN?

HCN (a q) ⇌ H^{+} (a q) + {CN}^{−} (a q) K_{c} = 4.9 \times 10^{−10}

Solution

Using “ x ” to represent the concentration of each product at equilibrium gives this ICE table.

This table has two main columns and four rows. The first row for the first column does not have a heading and then has the following: Initial pressure ( M ), Change ( M ), Equilibrium ( M ). The second column has the header, “H C N ( a q ) equilibrium arrow H superscript plus sign ( a q ) plus C N subscript negative sign ( a q ).” Under the second column is a subgroup of three columns and three rows. The first column has the following: 0.15, negative x, 0.15 minus x. The second column has the following: 0, x, x. The third column has the following: 0, x, x.

The exact solution may be obtained using the quadratic formula with

K_{c} = \frac{(x) (x)}{0.15 - x}

solving

x^{2} + 4.9 \times 10^{−10} - 7.35 \times 10^{−11} = 0

x = 8.56 \times 10^{−6} M (3 sig. figs.) = 8.6 \times 10^{−6} M (2 sig. figs.)

Thus [H ⁺ ] = [CN ^– ] = x = 8.6 $\times$ 10 ^–6 M and [HCN] = 0.15 – x = 0.15 M .

In this case, chemical intuition can provide a simpler solution. From the equilibrium constant and the initial conditions, x must be small compared to 0.15 M . More formally, if $x ≪ 0.15,$ then 0.15 – x ≈ 0.15. If this assumption is true, then it simplifies obtaining x

K_{c} = \frac{(x) (x)}{0.15 - x} \approx \frac{x^{2}}{0.15}

4.9 \times 10^{−10} = \frac{x^{2}}{0.15}

x^{2} = (0.15) (4.9 \times 10^{−10}) = 7.4 \times 10^{−11}

x = \sqrt{7.4 \times 10^{−11}} = 8.6 \times 10^{−6} M

In this example, solving the exact (quadratic) equation and using approximations gave the same result to two significant figures. While most of the time the approximation is a bit different from the exact solution, as long as the error is less than 5%, the approximate solution is considered valid. In this problem, the 5% applies to IF (0.15 – x ) ≈ 0.15 M , so if

\frac{x}{0.15} \times 100 % = \frac{8.6 \times 10^{−6}}{0.15} \times 100 % = 0.006 %

is less than 5%, as it is in this case, the assumption is valid. The approximate solution is thus a valid solution.

Check your learning

What are the equilibrium concentrations in a 0.25 M NH ₃ solution?

{NH}_{3} (a q) + H_{2} O (l) ⇌ {NH}_{4}^{+} (a q) + {OH}^{−} (a q) K_{c} = 1.8 \times 10^{−5}

Assume that x is much less than 0.25 M and calculate the error in your assumption.

Answer:

$[{OH}^{−}] = [{NH}_{4}^{+}] = 0.0021 M;$ [NH ₃ ] = 0.25 M , error = 0.84%

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The second example requires that the original information be processed a bit, but it still can be solved using a small x approximation.

Approximate solution after shifting starting concentration

Copper(II) ions form a complex ion in the presence of ammonia

{Cu}^{2+} (a q) + {4NH}_{3} (a q) ⇌ Cu {({NH}_{3})}_{4}^{2+} (a q) K_{c} = 5.0 \times 10^{13} = \frac{[Cu {({NH}_{3})}_{4}^{2+}]}{[{Cu}^{2+} (a q)] {[{NH}_{3}]}^{4}}

If 0.010 mol Cu ²⁺ is added to 1.00 L of a solution that is 1.00 M NH ₃ what are the concentrations when the system comes to equilibrium?

Solution

The initial concentration of copper(II) is 0.010 M . The equilibrium constant is very large so it would be better to start with as much product as possible because “all products” is much closer to equilibrium than “all reactants.” Note that Cu ²⁺ is the limiting reactant; if all 0.010 M of it reacts to form product the concentrations would be

[{Cu}^{2+}] = 0.010 - 0.010 = 0 M

[Cu {({NH}_{3})}_{4}^{2+}] = 0.010 M

[{NH}_{3}] = 1.00 - 4 \times 0.010 = 0.96 M

Using these “shifted” values as initial concentrations with x as the free copper(II) ion concentration at equilibrium gives this ICE table.

Since we are starting close to equilibrium, x should be small so that

0.96 + 4 x \approx 0.96 M

0.010 - x \approx 0.010 M

K_{c} = \frac{(0.010 - x)}{x {(0.96 - 4 x)}^{4}} \approx \frac{(0.010)}{x {(0.96)}^{4}} = 5.0 \times 10^{13}

x = \frac{(0.010)}{K_{c} {(0.96)}^{4}} = 2.4 \times 10^{−16} M

Select the smallest concentration for the 5% rule.

\frac{2.4 \times 10^{−16}}{0.010} \times 100 % = 2 \times 10^{−12} %

This is much less than 5%, so the assumptions are valid. The concentrations at equilibrium are

[{Cu}^{2+}] = x = 2.4 \times 10^{−16} M

[{NH}_{3}] = 0.96 - 4 x = 0.96 M

[Cu {({NH}_{3})}_{4}^{2+}] = 0.010 - x = 0.010 M

By starting with the maximum amount of product, this system was near equilibrium and the change ( x ) was very small. With only a small change required to get to equilibrium, the equation for x was greatly simplified and gave a valid result well within the 5% error maximum.

Check your learning

What are the equilibrium concentrations when 0.25 mol Ni ²⁺ is added to 1.00 L of 2.00 M NH ₃ solution?

{Ni}^{2+} (a q) + {6NH}_{3} (a q) ⇌ Ni {({NH}_{3})}_{6}^{2+} (a q) K_{c} = 5.5 \times 10^{8}

With such a large equilibrium constant, first form as much product as possible, then assume that only a small amount ( x ) of the product shifts left. Calculate the error in your assumption.

Answer:

$[Ni {({NH}_{3})}_{6}^{2+}] = 0.25 M,$ [NH ₃ ] = 0.50 M , [Ni ²⁺ ] = 2.9 $\times$ 10 ^–8 M , error = 1.2 $\times$ 10 ^–5 %

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Source: OpenStax, Chemistry. OpenStax CNX. May 20, 2015 Download for free at http://legacy.cnx.org/content/col11760/1.9

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