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Magazine Chapter 17: Problem 44
A 20.0-mL sample of \(0.150 \mathrm{MKOH}\) is titrated with \(0.125 \mathrm{M}\) \(\mathrm{HClO}_{4}\) solution. Calculate the pH after the following volumes of acid have been added: \((\mathbf{a}) 20.0 \mathrm{~mL},(\mathbf{b}) 23.0 \mathrm{~mL},\) (c) \(24.0 \mathrm{~mL}\) (d) \(25.0 \mathrm{~mL},\) (e) \(30.0 \mathrm{~mL}\).
Short Answer
Expert verified
The pH at each point of titration is: (a) 13.09, (b) 12.52, (c) 7.00, (d) 4.48, and (e) 3.93.
Step by step solution
01
Write the reaction equation between the base and the acid
The reaction between the strong base KOH and the strong acid HClO鈧 can be represented by the following balanced chemical equation:
\(KOH + HClO_4 \rightarrow KClO_4 + H_2O\)
02
Calculate the initial moles of KOH
We are given a 20.0 mL sample of 0.150 M KOH. To find the initial moles of KOH, use the formula:
moles = Molarity 脳 Volume in liters
moles of KOH = 0.150 M 脳 0.020 L = 0.003 mol
03
Calculate the moles of HClO鈧 added for each volume
The given concentration of HClO鈧 is 0.125 M. We will calculate the moles of HClO鈧 for the respective added volumes.
(a) 20.0 mL: moles of HClO鈧 = 0.125 M 脳 0.020 L = 0.00250 mol
(b) 23.0 mL: moles of HClO鈧 = 0.125 M 脳 0.023 L = 0.002875 mol
(c) 24.0 mL: moles of HClO鈧 = 0.125 M 脳 0.024 L = 0.00300 mol
(d) 25.0 mL: moles of HClO鈧 = 0.125 M 脳 0.025 L = 0.003125 mol
(e) 30.0 mL: moles of HClO鈧 = 0.125 M 脳 0.030 L = 0.00375 mol
04
Determine the pH at each point of titration
We know the relation between moles of KOH and moles of HClO鈧, pH can be calculated as follows:
(a) 0.003 mol KOH - 0.00250 mol HClO鈧 = 0.0005 mol KOH left
pH = 14 - pOH
pOH = -log(OH鈦 molarity)
pH = 14 - pOH(KOH) = 14 - (-log((0.0005 mol)/(0.040 L))) = 13.09
(b) 0.003 mol KOH - 0.002875 mol HClO鈧 = 0.000125 mol KOH left
pH = 14 - pOH(KOH) = 14 - (-log((0.000125 mol)/(0.043 L))) = 12.52
(c) 0.003000 mol KOH - 0.003000 mol HClO鈧 = 0 (neutralization point)
pH = 7
(d) 0.003000 mol KOH - 0.003125 mol HClO鈧 = 0.000125 mol HClO鈧 left (excess acid)
pH = -log(H鈦 molarity)
pH = -log((0.000125 mol)/(0.045 L)) = 4.48
(e) 0.003000 mol KOH - 0.003750 mol HClO鈧 = 0.00075 mol HClO鈧 left (excess acid)
pH = -log((0.00075 mol)/(0.050 L)) = 3.93
The pH at each point of titration is:
(a) 13.09
(b) 12.52
(c) 7.00
(d) 4.48
(e) 3.93
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Key Concepts
These are the key concepts you need to understand to accurately answer the question.
Acid-Base Reactions
Acid-base reactions are fundamental chemical reactions in which an acid reacts with a base to produce water and a salt. They are a key aspect of titration experiments. In our case, we have a reaction between a strong base, potassium hydroxide (KOH), and a strong acid, perchloric acid (\(\text{HClO}_4\)). This reaction can be represented in a simple balanced chemical equation as follows:
\[\text{KOH} + \text{HClO}_4 \rightarrow \text{KClO}_4 + \text{H}_2\text{O}\]
These reactions are crucial in determining various characteristics of a substance, such as pH levels, and are useful in applications like determining the concentration of unknown solutions.
\[\text{KOH} + \text{HClO}_4 \rightarrow \text{KClO}_4 + \text{H}_2\text{O}\]
- The strong base dissociates completely in water to produce hydroxide ions (OH鈦).
- The strong acid dissociates completely in water to produce hydrogen ions (\(\text{H}^+\)).
- In the reaction, the hydrogen ions from the acid combine with the hydroxide ions from the base to form water, a neutral compound.
These reactions are crucial in determining various characteristics of a substance, such as pH levels, and are useful in applications like determining the concentration of unknown solutions.
pH Calculation
Calculating the pH of a solution during a titration involves understanding the concentration of hydrogen ions in the solution. pH is a measure of how acidic or basic a solution is, with lower pH values being more acidic, higher values being more basic, and 7 being neutral.
The formula used to calculate pH is:
\[-\log[\text{H}^+]\]
For bases, we often calculate the pOH first, since bases release hydroxide ions (OH鈦) and not hydrogen ions directly. The pH can then be found using:
\[\text{pH} = 14 - \text{pOH}\]
By knowing the amounts of acid and base added, and any excess left, you can compute the exact pH at various stages of the titration.
The formula used to calculate pH is:
\[-\log[\text{H}^+]\]
For bases, we often calculate the pOH first, since bases release hydroxide ions (OH鈦) and not hydrogen ions directly. The pH can then be found using:
\[\text{pH} = 14 - \text{pOH}\]
- For a strong base like KOH, dissociate to give OH鈦, calculate the pOH using: \[\text{pOH} = -\log(\text{[OH鈦籡})\]
- The remaining concentration of OH鈦 determines how basic the solution is after reacting a specific amount of acid.
- For strong acids like HClO鈦, calculate pH directly from the concentration of remaining H鈦 ions after the base has been neutralized.
By knowing the amounts of acid and base added, and any excess left, you can compute the exact pH at various stages of the titration.
Neutralization Point
The neutralization point in a titration occurs when the amount of acid equals the amount of base, resulting in the formation of water and a salt, leaving no excess acid or base in the solution. In such reactions between strong acids and strong bases, this is known as the equivalence point, and it is where the pH is typically neutral, around 7.00.
In the given titration exercise:
Reaching the neutralization point is crucial for accurate chemical analysis, as it indicates the amount of substance needed to neutralize the other.
In the given titration exercise:
- Both KOH and HClO鈧 are completely dissociated in water, making it a perfect scenario for reaching a true neutralization point.
- The equivalence point is reached when 24.0 mL of 0.125 M HClO鈧 completely reacts with 20.0 mL of 0.150 M KOH.
- At this point, the moles of H鈦 from the acid equal the moles of OH鈦 from the base, resulting in pure water and a neutral pH of 7.00.
Reaching the neutralization point is crucial for accurate chemical analysis, as it indicates the amount of substance needed to neutralize the other.
Strong Acid and Strong Base Reaction
When strong acids and strong bases react, they undergo complete ionization, meaning they fully dissociate in water and react completely with each other to form water and a salt. This results in very distinct pH changes that are sharp and predictable.
Any added amount of the strong acid will be neutralized by an equivalent amount of the strong base, until one is in excess.
Such titrations provide a clear indication of pH changes at different stages, making them highly practical for determining concentration and thorough understanding of acid-base chemistry.
Any added amount of the strong acid will be neutralized by an equivalent amount of the strong base, until one is in excess.
- Before reaching the equivalence point, any added acid or base will lead to an increase in either H鈦 or OH鈦 concentration, depending on which is in excess, affecting the pH values significantly.
- If the base (like KOH) is in excess, the solution remains basic with a high pH.
- Once the equivalence point is surpassed, any additional acid results in the solution becoming acidic, reducing the pH rapidly.
Such titrations provide a clear indication of pH changes at different stages, making them highly practical for determining concentration and thorough understanding of acid-base chemistry.
