12.4.1 Expression for Ka

Cards (36)

The Ka expression is derived from the equilibrium constant expression.
The Ka expression for a generic acid HA is Ka = \frac{[H^{ + }][A^{ - }]}{[HA]}</latex>.
What does a lower Ka value indicate about an acid?
Weaker acid
What is the Ka value of Hydrochloric Acid ( $HCl$ )? 
$1.3 \times 10^{6}$
Acetic Acid ( $CH_{3}COOH$ ) is a weak acid.
The symbol $[H^{ + }]$ in the Ka expression represents the concentration of hydrogen ions.
What is the acid dissociation constant, Ka, a quantitative measure of?
Acid strength
The expression for $Ka$ is given by $Ka =$ $\frac{[H^{ + }][A^{ - }]}{[HA]}$ , where $[HA]$ represents the concentration of the undissociated acid
A higher $Ka$ value indicates a stronger acid.
Match the acid with its $Ka$ value and strength: 
Hydrochloric Acid ( $HCl$ ) ↔️ $1.3 × 10^{6}$ ||| Strong
Acetic Acid ( $CH_{3}COOH$ ) ↔️ $1.8 × 10^{ - 5}$ ||| Weak
Hydrocyanic Acid ( $HCN$ ) ↔️ $6.2 × 10^{ - 10}$ ||| Very Weak
The dissociation equation for a weak acid $HA$ in solution is $HA(aq) \rightleftharpoons H^ +$ $(aq) +$ $A^ - (aq)$ , where A^ -</latex> represents the conjugate base.
The double arrow in the dissociation equation of a weak acid indicates that the reaction is reversible.
Write the dissociation equation for acetic acid $(CH_{3}COOH)$ . 
$CH_{3}COOH(aq) \rightleftharpoons H^ +$ $(aq) +$ $CH_{3}COO^ - (aq)$
The expression for $Ka$ is derived from the equilibrium constant expression: $Ka =$ $\frac{[H^{ + }][A^{ - }]}{[HA]}$ , where $[HA]$ is the concentration of the undissociated acid
What is the dissociation equation for a generic acid $HA$ in water? 
$HA(aq) \rightleftharpoons H^{ + }(aq) +$ $A^{ - }(aq)$
The acid dissociation constant $Ka$ is derived from the equilibrium constant expression.
The Ka expression for a generic acid HA is $Ka =$ $\frac{[H^{ + }][A^{ - }]}{[HA]}$ .
Give an example of a strong acid.
Hydrochloric Acid ( $HCl$ )
Match the component in the Ka expression with its meaning:
$[H^{ + }]$ ↔️ Concentration of hydrogen ions
$[A^{ - }]$ ↔️ Concentration of conjugate base
$[HA]$ ↔️ Concentration of undissociated acid
Steps to derive the Ka expression from the dissociation equation
1️⃣ Write the dissociation equation for a generic acid $HA$
2️⃣ Express the equilibrium constant for the dissociation
3️⃣ Define the terms in the equilibrium constant expression
4️⃣ Write the final Ka expression
The acid dissociation constant $Ka$ is a quantitative measure of the strength of an acid in solution.
What does a higher Ka value indicate about an acid?
Stronger acid
Hydrochloric acid has a higher Ka value than acetic acid.
$HA$ in the dissociation equation represents the undissociated weak acid.
Write the dissociation equation for acetic acid ( $CH_{3}COOH$ ). 
$CH_{3}COOH(aq) \rightleftharpoons H^ +$ $(aq) +$ $CH_{3}COO^ - (aq)$
Strong acids undergo irreversible reactions, while weak acids undergo reversible reactions.
List the key components in the Ka expression for a generic acid $HA$ . 
$[H^{ + }], [A^{ - }], [HA]$
Match the components of the Ka expression with their meanings:
$[H^{ + }]$ ↔️ Concentration of hydrogen ions
$[A^{ - }]$ ↔️ Concentration of conjugate base
$[HA]$ ↔️ Concentration of undissociated acid
What does a higher Ka value indicate about an acid's strength?
Stronger acid
A lower Ka value indicates a weaker acid.
Order the following acids from strongest to weakest based on their Ka values:
1️⃣ Hydrochloric Acid (1.3 \times10^{6}</latex>)
2️⃣ Acetic Acid ( $1.8 \times 10^{ - 5}$ )
3️⃣ Hydrocyanic Acid ( $6.2 \times 10^{ - 10}$ )
Match the acid with its approximate Ka value and acid strength:
Hydrochloric Acid ↔️ $1.3 \times 10^{6}$ , Strong
Acetic Acid ↔️ $1.8 \times 10^{ - 5}$ , Weak
Hydrocyanic Acid ↔️ $6.2 \times 10^{ - 10}$ , Very Weak
Why is Hydrochloric Acid considered a strong acid based on its Ka value?
High Ka value
The Ka value is significant in understanding the relative strengths of acids.
The Ka expression is derived from the equilibrium constant for the dissociation of an acid.
What does the Ka value help predict in acid-base equilibria?
Extent of dissociation