Question #bde65

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Question #bde65

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Answer 1 · 2015-06-18T09:03:33

Because when you add sulfuric acid to water, the protonation of water molecules takes place.

Explanation:

Hydrogen sulfate, or bisulfate ion, as you'll sometimes see it called, cannot act as a conjugate base in solution because sulfuric acid, $H_{2} S O_{4}$ $H_2SO_4$ , is a strong acid that dissociates completely.

In other words, in the first dissociation of sulfuric acid, the equilibrium that forms hydronium ions, $H_{3} O^{+}$ $H_3O^(+)$ and hydrogen sulfate lies so far to the right that, for all intended purposes, you can consider that no sulfuric acid molecules remain undissociated.

$H_{2} S O_{4 (a q)} + H_{2} O_{(l)} ⇌ H_{3} O_{(a q)}^{+} + H S O_{4 (a q)}^{-}$ $H_2SO_(4(aq)) + H_2O_((l)) rightleftharpoons H_3O_((aq))^(+) + HSO_(4(aq))^(-)$ , $K_{a 1} = 2.4 \cdot 10^{6}$ $K_(a1) = 2.4 * 10^6$

Notice the very large value of the acid dissociation constant, $K_{a}$ $K_a$ . In theory, $H S O_{4}^{-}$ $HSO_4^(-)$ , being the conjugate base of sulfuric acid, can pick up a proton to reform sulfuric acid. However, for practical purposes, the dissociation of sulfuric acid can be seen as going to completetion because of the very large $K_{a}$ $K_a$ .

$H_{2} S O_{4 (a q)} + H_{2} O_{(l)} \to H_{3} O_{(a q)}^{+} + H S O_{4 (a q)}^{-}$ $H_2SO_(4(aq)) + H_2O_((l)) -> H_3O_((aq))^(+) + HSO_(4(aq))^(-)$

So, when you place sulfuric acid in water (never do the other way around!), all the sulfuric acid molecules will lose their proton, which is then picked up by water molecules $\to$ $->$ hydronium is formed.

![http://webgenchem.com/gc2600012.htm]( useruploads.socratic.org )

Once this happens, you can consider that the solution no longer contains $H_{2} S O_{4}$ $H_2SO_4$ molecules. Hydrogen sulfate goes on to act as a weak acid, donating its proton to form bisulfate ions, $S O_{4}^{2 -}$ $SO_4^(2-)$ .

However, hydrogen sulfate is a weak acid and thus cannot dissociate completely.

$H S O_{4 (a q)}^{-} + H_{2} O_{(l)} ⇌ H_{3} O_{(a q)}^{+} + S O_{4 (a q)}^{2 -}$ $HSO_(4(aq))^(-) + H_2O_((l)) rightleftharpoons H_3O_((aq))^(+) + SO_(4(aq))^(2-)$ , $K_{a 2} = 1.0 \cdot 10^{- 2}$ $K_(a2) = 1.0 * 10^(-2)$

This means that your solution will contain both hydrogen sulfate and bisulfate ions.

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Question #bde65

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