Problem 43
Question
Calculate the \(\mathrm{pOH}\) and \(\mathrm{pH}\) of the following aqueous solutions at \(25^{\circ} \mathrm{C}:\) (a) \(1.24 \mathrm{M} \mathrm{LiOH},\) (b) \(0.22 \mathrm{M}\) \(\mathrm{Ba}(\mathrm{OH})_{2}\) (c) \(0.085 \mathrm{M} \mathrm{NaOH}\).
Step-by-Step Solution
Verified Answer
(a) pH = 13.1, (b) pH = 13.7, (c) pH = 12.9.
1Step 1: Understanding the Relationship
For any base M(OH)_n, if we know the concentration 'c' of the base, the hydroxide ion concentration,
[OH^-], is given by n × c.
2Step 2: Calculating [OH^-]
(a) For 1.24 M LiOH, which dissociates completely into Li^+ and OH^-, [OH^-] = 1.24 M.
(b) For 0.22 M Ba(OH)_2, which provides two OH^- ions per formula unit, [OH^-] = 2 × 0.22 = 0.44 M.
(c) For 0.085 M NaOH, [OH^-] = 0.085 M since it dissociates completely into Na^+ and OH^-.
3Step 3: Calculating pOH
Use the formula pOH = -log[OH^-].
(a) pOH for 1.24 M LiOH: pOH = -log(1.24).
(b) pOH for 0.44 M Ba(OH)_2: pOH = -log(0.44).
(c) pOH for 0.085 M NaOH: pOH = -log(0.085).
4Step 4: Calculating pH
Use the relationship pH + pOH = 14 at 25°C.
(a) pH = 14 - pOH for 1.24 M LiOH.
(b) pH = 14 - pOH for 0.44 M Ba(OH)_2.
(c) pH = 14 - pOH for 0.085 M NaOH.
Key Concepts
Strong BasesHydroxide Ion ConcentrationDissociation of BasespH and pOH Relationship
Strong Bases
Strong bases are compounds that can completely dissociate in water. This means they separate into their component ions when dissolved. For example, some common strong bases include lithium hydroxide (LiOH), sodium hydroxide (NaOH), and barium hydroxide (Ba(OH)_2).
Strong bases play a crucial role in chemistry because of their ability to increase the concentration of hydroxide ions in a solution. This makes them excellent for neutralizing acids. In practice, when strong bases are added to water, they will fully break apart, unlike weak bases, which only partially dissociate.
In summary, when dealing with strong bases, you can expect them to completely dissociate, making calculations more straightforward. For instance, 1 mole of LiOH will give 1 mole of hydroxide ions.
Strong bases play a crucial role in chemistry because of their ability to increase the concentration of hydroxide ions in a solution. This makes them excellent for neutralizing acids. In practice, when strong bases are added to water, they will fully break apart, unlike weak bases, which only partially dissociate.
In summary, when dealing with strong bases, you can expect them to completely dissociate, making calculations more straightforward. For instance, 1 mole of LiOH will give 1 mole of hydroxide ions.
Hydroxide Ion Concentration
The concentration of hydroxide ions, \([OH^-]\), in a solution is an essential factor in understanding the basicity of that solution. When a base like Ba(OH)2 dissociates, it breaks apart to release hydroxide ions. For every molecule of \( ext{Ba(OH)2}\), there are two hydroxide ions released.
Calculating the \([OH^-]\) is straightforward with strong bases. For a solution of \(0.22 \, ext{M} \, ext{Ba(OH)2}\), since it releases two hydroxide ions per formula unit, the concentration would be \(2 \times 0.22 = 0.44 \, ext{M}\).
This measurement not only tells us how basic a solution is but also helps in determining the pH and pOH values.
Calculating the \([OH^-]\) is straightforward with strong bases. For a solution of \(0.22 \, ext{M} \, ext{Ba(OH)2}\), since it releases two hydroxide ions per formula unit, the concentration would be \(2 \times 0.22 = 0.44 \, ext{M}\).
This measurement not only tells us how basic a solution is but also helps in determining the pH and pOH values.
Dissociation of Bases
The dissociation process is when a compound breaks into simpler constituents or fragments. In the context of strong bases like NaOH, dissociation refers to the complete separation of its ions in an aqueous solution.
When NaOH dissociates, it yields sodium ions \(\text{(Na}^+\text{)}\) and hydroxide ions \(\text{(OH}^-\text{)}\). This complete dissociation distinguishes strong bases from weak bases, which only partially separate in water.
Understanding this process is key in chemistry, as it explains why some solutions exhibit greater basicity. The complete dissociation into ions allows those ions to interact in further reactions, significantly influencing the pH of the solution.
When NaOH dissociates, it yields sodium ions \(\text{(Na}^+\text{)}\) and hydroxide ions \(\text{(OH}^-\text{)}\). This complete dissociation distinguishes strong bases from weak bases, which only partially separate in water.
Understanding this process is key in chemistry, as it explains why some solutions exhibit greater basicity. The complete dissociation into ions allows those ions to interact in further reactions, significantly influencing the pH of the solution.
pH and pOH Relationship
The relationship between pH and pOH is fundamental in chemistry, especially when dealing with acid-base reactions. At room temperature (25°C), this relationship is expressed through the equation:\[\text{pH} + \text{pOH} = 14\]
This important formula allows us to interconvert between pH and pOH values. For instance, if the pOH of a solution is calculated and found to be 1.5, the pH can be determined by subtracting 1.5 from 14, yielding a pH of 12.5.
It's crucial to grasp this link, as it provides insight into the acidity or basicity of a solution. When dealing with basic solutions, the pOH is often more direct to calculate, helping to quickly analyze the properties of the solution.
This important formula allows us to interconvert between pH and pOH values. For instance, if the pOH of a solution is calculated and found to be 1.5, the pH can be determined by subtracting 1.5 from 14, yielding a pH of 12.5.
It's crucial to grasp this link, as it provides insight into the acidity or basicity of a solution. When dealing with basic solutions, the pOH is often more direct to calculate, helping to quickly analyze the properties of the solution.
Other exercises in this chapter
Problem 41
Calculate the concentration of \(\mathrm{HNO}_{3}\) in a solution at \(25^{\circ} \mathrm{C}\) that has a \(\mathrm{pH}\) of \((\mathrm{a}) 4.21,(\mathrm{~b}) 3
View solution Problem 42
Calculate the \(\mathrm{pOH}\) and \(\mathrm{pH}\) of the following aqueous solutions at \(25^{\circ} \mathrm{C}:\) (a) \(0.066 \mathrm{M} \mathrm{KOH},\) (b) \
View solution Problem 44
An aqueous solution of a strong base has a pH of 9.78 at \(25^{\circ} \mathrm{C}\). Calculate the concentration of the base if the base is (a) \(\mathrm{LiOH}\)
View solution Problem 45
An aqueous solution of a strong base has a pH of 11.04 at \(25^{\circ} \mathrm{C}\). Calculate the concentration of the base if the base is (a) \(\mathrm{KOH}\)
View solution