How to calculate Kb from Ka? - (Ka to Kb)

Weak acids and bases dissociate to a small extent in an aqueous solution. A weak acid (HA) breaks down in the water to give H⁺ ions, while a weak base (B) dissociates to produce OH^– ions.

The extent of ionization of a weak acid or base in an aqueous solution can be determined by using ionization constants, i.e., K_a and K_b.

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What is K_a?

K_a stands for acid dissociation constant.

The ionization equilibrium for the dissociation of a weak acid (HA) in an aqueous solution is represented as follows:

The acid dissociation constant (K_a) for the above reaction can be represented as equation (i).

$Ka = \frac{[H_{3}O^{+}][A^{-}]}{[HA][H_{2}O]}$ ………. Equation (i)

Where;

[H₃O⁺] = concentration of hydronium ions formed in the aqueous solution
[A^–] = concentration of conjugate base of the acid
[HA] = acid concentration at equilibrium
[H₂O] = concentration of water

As water concentration stays constant throughout the reaction, while [H₃O⁺] = [H⁺], i.e., the concentration of H⁺ ions released in the aqueous solution. So, equation (i) can be rearranged as equation (ii).

$Ka = \frac{[H^{+}][A^{-}]}{[HA]}$ ………. Equation (ii)

The greater the strength of an acid, the higher the K_a value for its aqueous solution and vice versa.

What is K_b?

K_b represents the base dissociation constant.

The ionization equilibrium for the dissociation of a weak base (B) in an aqueous solution is represented as:

The base dissociation constant (K_b) for the above reaction can be represented as equation (iii).

$Kb = \frac{[BH^{+}][OH^{-}]}{[B][H_{2}O]}$ ………. Equation (iii)

Where;

[BH⁺] = concentration of conjugate acid of the base
[OH^–] = hydroxide ion concentration in aqueous solution
[B]= concentration of base at equilibrium

Considering the water concentration [H₂O] constant, equation (iii) can be rearranged as shown below.

$Kb = \frac{[BH^{+}][OH^{-}]}{[B]}$ ………. Equation (iv)

The greater the strength of a base, the higher the K_b value for its aqueous solution.

What is the relationship between K_a and K_b?

K_a and K_b can be interconverted using another chemical entity called the water dissociation constant (K_w), as shown in equation (v).

K_a. K_b = K_w………. Equation (v)

⇒ K_w= [H⁺] [OH^–]

The value of K_w is fixed at 25^°C, i.e., room temperature. K_w = 1.0 x 10^-14.

As per equation (v), if the value of K_a is known, we can easily determine the value of K_b by making K_b the subject of the formula.

Now let’s see how we can find K_b from K_a through the different examples given below.

Solved examples for finding K_bfrom K_a (K_a to K_b)

Example #1: The acid dissociation constant (K_a) for acetic acid (CH₃COOH) at room temperature is 1.8 x 10^-5. What is the base dissociation constant (K_b) for sodium acetate (CH₃COO^–Na⁺)?

As per the above statement, K_a = 1.8 x 10^-5. We already know the value of K_w at r.t.p, i.e., K_w = 1.0 x 10^-14.

We can calculate the value of K_b as follows:

⇒ K_b = K_w/k_a

∴ K_b= $\frac{1.0\times10^{-14}}{1.8\times10^{-5}}$ = 5.6 x 10^-10.

Result: The base dissociation constant (K_b) for CH₃COO^–Na⁺ is 5.6 x 10^-10.

Acetic acid and acetate ions are known as conjugate acid-base pairs.

Example #2: Ammonium (NH₄⁺) ion is a mildly strong conjugate acid of a weak base, i.e., ammonia (NH₃). The K_aof NH₄⁺ is 5.6 x 10^-10. What is K_b for NH₃?

As the K_a value is given so we can easily determine the K_b value for NH₃ using the expression K_b = K_w/K_a.

⇒ K_b = K_w/K_a

∴ K_b = $\frac{1.0\times10^{-14}}{5.6\times10^{-10}}$ = 1.8 x 10^-5.

Result: The base dissociation constant (K_b) for NH_3, as per the above information, is 1.8 x 10^-5.

Example # 3: As per Peter’s experimental data, the pH of a 0.500 M formic acid (HCOOH) solution is measured to be 2.04. How can we determine the K_b value for formate ion (HCOO^–) using this data?

Formic acid and formate ion are conjugate acid-base pairs.

Formic acid dissociates in an aqueous solution, as shown below.

Formic acid dissociates in an aqueous solution

So if we first calculate the acid dissociation constant (K_a) value for formic acid, we can easily determine the K_b value for formate ion.

The K_a value of formic acid can be calculated using equation (ii), which we learned at the beginning of the article.

K_a = $\frac{[H^{+}][A^{-}]}{[HA]}$

For formic acid, the above equation can be transformed into:

K_a = $\frac{[H^{+}][HCOO^{-}]}{[HCOOH]}$

[H⁺] can be determined from the pH given in the question statement.

pH = -log [H⁺]

Making [H⁺] the subject of the formula.

[H⁺] = 10^-pH

[H⁺] = 10^-2.04 = 9.12 x 10^-3 M

As per the above reaction equation, [H⁺] = [HCOO^–] = 9.12 X 10^-3 M

[HCOOH] = formic acid concentration at equilibrium = initial acid concentration – [H⁺]

The initial formic acid concentration is given in the question statement, i.e., 0.500 M.

[HCOOH]_equilibrium= 0.500 – (9.12 X 10^-3) = 0.491 M.

Finally, we need to plug in all the values determined above into the K_a formula.

K_a= $\frac{(9.12\times10^{-3})(9.12\times10^{-3})}{(0.491)}$ = 1.7 x 10^-4

Now that we have the K_a of formic acid, we can easily determine the K_b value for formate ion using K_b = K_w/K_a.

∴ K_b= $\frac{(1.0\times10^{-14})}{(1.7\times10^{-4})}$ = 5.9 × 10^-11.

Result: The base dissociation constant (K_b) value for formate ion as per the above data is 5.9 x 10^-11.

Example # 4: The pK_a for hydrofluoric acid (HF) at 25°C is 3.36. How can we use this information to determine K_b for F^– (the conjugate base of HF)?

The pK_a value for the acidic solution is related to its K_a by the formula given below.

pK_a = -log K_a or K_a = 10^-pKa

As given in the question statement, pK_afor HF = 3.36 so, its K_a = 10^-3.36 = 4.4 x 10^-4.

Now that we know K_a for HF, we can easily find K_b for F^– as follows:

∴ K_b = K_w/k_a

∴ K_b = $\frac{(1.0\times10^{-14})}{(4.4\times10^{-4})}$ = 2.2 x 10^-11.

Result: The base dissociation constant (K_b) value for fluoride (F^–) ion is 2.2 x 10^-11 at 25°C.

Also, check:

FAQ

What is K_a?

K_a is defined as the acid dissociation constant. It determines the extent of ionization of usually a weak acid in an aqueous solution.

A higher K_a value denotes that the respective acid breaks down to a large extent in water, i.e., it has a higher strength.

What is K_b?

K_bstands for the base dissociation constant that determines the extent of ionization of a base in an aqueous solution.

How do you differentiate between an acid and a base?

Acids break down to release H⁺ ions in water, while a base breaks down to produce OH^– ions in water.

Acids are also defined as proton donors, while bases are proton acceptors as per the Bronsted Lowry acid-base theory.

How to differentiate between an acid and a base

Also read:

How to tell if an acid or base is strong or weak?

How to tell if something is an acid or base?

What is the relationship between K_aand K_b?

The product of K_a and K_b is equal to K_w, i.e., the water dissociation constant.

K_w = K_a. K_b

How to find K_b from K_a?

The value of K_w is fixed at room temperature (25°C), i.e., K_w = 1.0 x 10^-14. If the value of K_a of acid is known, then the value for its conjugate base can be determined by rearranging the expression K_w = K_a. K_b, making K_b the subject of the formula, as shown below.

∴ K_b= K_w/K_a

What is a conjugate acid-base pair?

According to the Bronsted-Lowry theory of acids and bases, a weak acid, such as acetic acid (CH₃COOH), dissociates to a small extent in an aqueous solution by releasing H⁺ ions.

The acid molecule is converted into an ion by the loss of a proton. This ion is known as the conjugate base of the acid.

For e.g. CH₃COOH dissociates into acetate (CH₃COO^–) by losing an H⁺ ion.

Consequently, CH₃COOH and CH₃COO^– is known as a conjugate acid-base pair.

How are K_a and K_b related to the strength of an acid or a base?

The higher the K_a or K_b value, the greater the strength of the respective acid or base.

Is there a numerical relation between the pH of an acidic solution and its K_a value?

Yes. The K_a of an acidic solution can be used to find pK_a as follows:

⇒ pK_a = -log K_a

pK_ais directly related to pH as follows:

⇒ pH = pK_a + log [A^–]/[HA]

In short, the pH of an acidic solution is inversely related to its K_a value.

The greater the acidic strength, the higher the K_a value, but the lower its pH.

Summary

The extent of ionization of a weak acid or base in an aqueous solution can be determined using their K_a and K_b values, respectively.
K_a represents the acid dissociation constant.
K_b stands for base dissociation constant.
Greater the strength of an acid or base, the higher the respective dissociation constant values because the latter ionizes to a larger extent in an aqueous solution.
K_a is related to K_b by the equation K_w = K_a.K_b.
If the value of K_a for acid is known, the K_b value for its conjugate base can be determined by rearranging the expression: K_b = K_w/K_a.
K_w = 1.0 x 10^-14 at 25°

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Ammara Waheed

Ammara Waheed is a highly qualified and experienced chemist, whose passion for Chemistry is evident in her writing. With a Bachelor of Science (Hons.) and Master of Philosophy (M. Phil) in Physical and Analytical Chemistry from Government College University (GCU) Lahore, Pakistan, with a hands-on laboratory experience in the Pakistan Council of Scientific and Industrial Research (PCSIR), Ammara has a solid educational foundation in her field. She comes from a distinguished research background and she documents her research endeavors for reputable journals such as Wiley and Elsevier. Her deep knowledge and expertise in the field of Chemistry make her a trusted and reliable authority in her profession. Let's connect - https://www.researchgate.net/profile/Ammara-Waheed

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How to calculate Kb from Ka? - (Ka to Kb)

What is K_a?

What is K_b?

What is the relationship between K_a and K_b?

Solved examples for finding K_bfrom K_a (K_a to K_b)