Question #50ffd

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Question #50ffd

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Answer 1 · 2015-06-20T13:28:50

Here's how you'd go about solving this one.

Explanation:

!! LONG ANSWER !!

So, you have a solution that contains barium carbonate, $B a C O_{3}$ $BaCO_3$ , to which you add calcium carbonate, $C a C O_{3}$ $CaCO_3$ . The concentration of the carbonate ions will be affected by the fact that you have 2 insoluble compounds that release carbonate ions in solution.

More specifically, the saturated barium carbonate solution will influence the molar solubility of the calcium carbonate solution. This happens because of the common ion effect - the carbonate ions released into solution by the barium carbonate will change the solubility of the added calcium carbonate.

So, you know that you're dealing with a 1-L, saturated solution of barium carbonate, an insoluble compound. This means that your solution contains all the dissolved barium carbonate it can possibly support at that temperature.

This means that you can use the solubility product constant, $K_{s p}$ $K_(sp)$ , to determine the molar solubility of your compound, i.e. how many moles of barium carbonate actually dissolve in a 1-L solution.

Use an ICE table to help you with that

$B a C O_{3 (s)} \to B a_{(a q)}^{2 +} + C O_{3 (a q)}^{2 -}$ $" "BaCO_(3(s)) -> Ba_((aq))^(2+) + CO_(3(aq))^(2-)$
I........ $-$ $-$ .....................0...............0
C...... $-$ $-$ .....................(+x)...........(+x)
E....... $-$ $-$ .......................x...............x

By definition, $K_{s p}$ $K_(sp)$ will be

$K_{s p} = [B a^{2 +}] \cdot [C O_{3}^{2 -}] = x \cdot x = x^{2}$ $K_(sp) = [Ba^(2+)] * [CO_3^(2-)] = x * x = x^2$

Therefore,

$6.61 \cdot 10^{- 9} = x^{2} \Rightarrow x = \sqrt{6.61 \cdot 10^{- 9}} = 8.1 \cdot 10^{- 5}$ $6.61 * 10^(-9) = x^2 => x = sqrt(6.61 * 10^(-9)) = 8.1 * 10^(-5)$

This means that concentration of the carbonate ion, $C O_{3}^{2 -}$ $CO_3^(2-)$ , is equal to $8.1 \cdot 10^{- 5} M$ $8.1 * 10^(-5)"M"$ .

Now you add enough calcium carbonate to the solution. Once again, use an ICE table to help you with the calculations. Keep in mind that the initial concentration of carbonate ions is $8.1 \cdot 10^{- 5} M$ $8.1*10^(-5)"M"$ .

$C a C O_{3 (s)} \to C a_{(a q)}^{2 +} + C O_{3 (a q)}^{2 -}$ $" "CaCO_(3(s)) -> Ca_((aq))^(2+) + CO_(3(aq))^(2-)$
I........ $-$ $-$ ......................0.............. $8.1 \cdot 10^{- 5}$ $8.1* 10^(-5)$
C...... $-$ $-$ .....................(+x)................(+x)
E....... $-$ $-$ .......................x............... $8.1 \cdot 10^{- 5} + x$ $8.1*10^(-5)+x$

The solubility equilibrium constant of the calcium carbonate will be

$K_{s p} = [C a^{2 +}] \cdot [C O_{3}^{2 -}]$ $K_(sp) = [Ca^(2+)] * [CO_3^(2-)]$

$K_{s p} = x \cdot (8.1 \cdot 10^{- 5} + x) = 5.49 \cdot 10^{- 10}$ $K_(sp) = x * (8.1 * 10^(-5)+x) = 5.49 * 10^(-10)$

This is equivalent to

$x^{2} + 8.1 \cdot 10^{- 5} x - 5.49 \cdot 10^{- 10} = 0$ $x^2 + 8.1 * 10^(-5)x - 5.49 * 10^(-10) = 0$

Solving this quadratic equation for $x$ $x$ will produce only one suitable value, which is

$x = 6.29 \cdot 10^{- 6} M$ $x = 6.29 * 10^(-6)"M"$

The molar solubility of the calcium carbonate decreases because of the presence of the carbonate ions.

The final concentration ofcarbonate ions in solution will be

$[C O_{3}^{2 -}] = 8.1 \cdot 10^{- 5} + 6.29 \cdot 10^{- 6} = 8.73 \cdot 10^{- 5} M$ $[CO_3^(2-)] = 8.1 * 10^(-5) + 6.29 * 10^(-6) = 8.73 * 10^(-5)"M"$

Now, in aquesous solution, the carbonate ion will react with water to form the bicarbonate ion, $H C O_{3}^{-}$ $HCO_3^(-)$ , and hydroxide ions, $O H^{-}$ $OH^(-)$ . Once again, use an ICE table to help you with the calculations

$C O_{3 (a q)}^{2 -} + H_{2} O_{(l)} ⇌ H C O_{3 (a q)}^{-} + O H_{(a q)}^{-}$ $" "CO_(3(aq))^(2-) + H_2O_((l)) rightleftharpoons HCO_(3(aq))^(-) + OH_((aq))^(-)$
I... $8.73 \cdot 10^{- 5}$ $8.73 * 10^(-5)$ .............................0.....................0
C.......(-x).....................................(+x).................(+x)
E... $8.73 \cdot 10^{- 5} - x$ $8.73*10^(-5)-x$ .....................x......................x

Since the carbonate ion results from the second dissociation of carbonic acid, $H_{2} C O_{3}$ $H_2CO_3$ , you're going to have to use $K_{a 2}$ $K_(a2)$ to determine $K_{b}$ $K_b$ .

$K_{b} = \frac{10^{- 14}}{K_{a 2}} = \frac{10^{- 14}}{5.6 \cdot 10^{- 11}} = 1.79 \cdot 10^{- 4}$ $K_b = 10^(-14)/K_(a2) = 10^(-14)/(5.6 * 10^(-11)) = 1.79 * 10^(-4)$

Therefore, you have

$K_{b} = \frac{[H C O_{3}^{-}] \cdot [O H^{-}]}{[C O_{3}^{2 -}]} = \frac{x \cdot x}{8.73 \cdot 10^{- 5} - x}$ $K_b = ([HCO_3^(-)] * [OH^(-)])/([CO_3^(2-)]) = (x * x)/(8.73 * 10^(-5) - x)$

This will eventually get you

$x^{2} + 1.79 \cdot 10^{- 4} x - 1.56 \cdot 10^{- 8} = 0$ $x^2 + 1.79 * 10^(-4)x - 1.56 * 10^(-8) = 0$

The only acceptable solution for this quadratic equation is

$x = 6.41 \cdot 10^{- 5}$ $x = 6.41 * 10^(-5)$

The concentration of hydroxide ions will thus be

$[O H^{-}] = x = 6.41 \cdot 10^{- 5} M$ $[OH^(-)] = x = 6.41 * 10^(-5)"M"$

The pOH of the solution will be

$p O H = - log ([O H^{-}]) = - log (6.41 \cdot 10^{- 5}) = 4.20$ $pOH = - log([OH^(-)]) = -log(6.41 * 10^(-5)) = 4.20$

The pH of the solution will thus be

$p H_{sol} = 14 - p O H = 14 - 4.20 = 9.80$ $pH_"sol" = 14 - pOH = 14 - 4.20 = color(green)(9.80)$

The concentrations of the other compounds will be

$[H C O_{3}^{-}] = 6.41 \cdot 10^{- 5} M$ $[HCO_3^(-)] = 6.41 * 10^(-5)"M"$
$[C O_{3}^{2 -}] = 2.32 \cdot 10^{- 5} M$ $[CO_3^(2-)] = 2.32 * 10^(-5)"M"$
$[B a^{2 +}] = 8.1 \cdot 10^{- 5} M$ $[Ba^(2+)] = 8.1 * 10^(-5)"M"$
$[C a^{2 +}] = 8.73 \cdot 10^{- 5} M$ $[Ca^(2+)] = 8.73 * 10^(-5)"M"$
$[O H^{-}] = 6.41 \cdot 10^{- 5} M$ $[OH^(-)] = 6.41 * 10^(-5)"M"$

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