Because acetic acid is a stronger acid than water, it must also be a weaker base, with a lesser tendency to accept a proton than \(H_2O\). Measurements of the conductivity of 0.1 M solutions of both HI and \(HNO_3\) in acetic acid show that HI is completely dissociated, but \(HNO_3\) is only partially dissociated and behaves like a weak acid in this solvent. This result clearly tells us that HI is a stronger acid than \(HNO_3\). The relative order of acid strengths and approximate \(K_a\) and \(pK_a\) values for the strong acids at the top of Table \(\PageIndex<1>\) were determined using measurements like this and different nonaqueous solvents.
When you look at the aqueous choices, \(H_3O^+\) ’s the strongest acid and you will \(OH^?\) ’s the most effective legs that can exists inside balance that have \(H_2O\).
The leveling effect applies to solutions of strong bases as well: In aqueous solution, any base stronger than OH? is leveled to the strength of OH? because OH? is the strongest base that can exist in equilibrium with water. Salts such as \(K_2O\), \(NaOCH_3\) (sodium methoxide), and \(NaNH_2\) (sodamide, or sodium amide), whose anions are the conjugate bases of species that would lie below water in Table \(\PageIndex<2>\), dating sites for Milf Sites adults are all strong bases that react essentially completely (and often violently) with water, accepting a proton to give a solution of \(OH^?\) and the corresponding cation:
Polyprotic Acids and Angles
Because you read, polyprotic acids such as for instance \(H_2SO_4\), \(H_3PO_4\), and \(H_2CO_3\) contain more than you to definitely ionizable proton, and protons is actually destroyed for the a great stepwise fashion. New completely protonated species is always the most powerful acid because is a lot easier to eradicate a good proton regarding a basic molecule than just off an effective adversely recharged ion. Therefore acid energy decrease on the loss of then protons, and you will, respectively, the new \(pK_a\) expands. Consider \(H_2SO_4\), like:
The hydrogen sulfate ion (\(HSO_4^?\)) is both the conjugate base of \(H_2SO_4\) and the conjugate acid of \(SO_4^<2?>\). Just like water, HSO4? can therefore act as either an acid or a base, depending on whether the other reactant is a stronger acid or a stronger base. Conversely, the sulfate ion (\(SO_4^<2?>\)) is a polyprotic base that is capable of accepting two protons in a stepwise manner:
In contrast, in the second reaction, appreciable quantities of both \(HSO_4^?\) and \(SO_4^<2?>\) are present at equilibrium
Like any other conjugate acidbase pair, the strengths of the conjugate acids and bases are related by \(pK_a\) + \(pK_b\) = pKw. Consider, for example, the \(HSO_4^?/ SO_4^<2?>\) conjugate acidbase pair. From Table \(\PageIndex<1>\), we see that the \(pK_a\) of \(HSO_4^?\) is 1.99. Hence the \(pK_b\) of \(SO_4^<2?>\) is ? 1.99 = . Thus sulfate is a rather weak base, whereas \(OH^?\) is a strong base, so the equilibrium shown in Equation \(\ref<16.6>\) lies to the left. The \(HSO_4^?\) ion is also a very weak base (\(pK_a\) of \(H_2SO_4\) = 2.0, \(pK_b\) of \(HSO_4^? = 14 ? (?2.0) = 16\)), which is consistent with what we expect for the conjugate base of a strong acid.
- \(NH^+_<4(aq)>+PO^<3?>_ <4(aq)>\rightleftharpoons NH_<3(aq)>+HPO^<2?>_<4(aq)>\)
- \(CH_3CH_2CO_2H_< (aq)>+CN^?_ < (aq)>\rightleftharpoons CH_3CH_2CO^?_<2(aq)>+HCN_< (aq)>\)
Identify the conjugate acidbase pairs in each reaction. Then refer to Tables \(\PageIndex<1>\)and\(\PageIndex<2>\) and Figure \(\PageIndex<2>\) to determine which is the stronger acid and base. Equilibrium always favors the formation of the weaker acidbase pair.
The conjugate acidbase pairs are \(NH_4^+/NH_3\) and \(HPO_4^<2?>/PO_4^<3?>\). According to Tables \(\PageIndex<1>\) and \(\PageIndex<2>\), \(NH_4^+\) is a stronger acid (\(pK_a = 9.25\)) than \(HPO_4^<2?>\) (pKa = ), and \(PO_4^<3?>\) is a stronger base (\(pK_b = 1.68\)) than \(NH_3\) (\(pK_b = 4.75\)). The equilibrium will therefore lie to the right, favoring the formation of the weaker acidbase pair:
