Acid-Base Titrations (College Board AP® Chemistry): Exam Questions

1 hour22 questions
1a
1 point

Acetic acid, CH3COOH, is titrated with NaOH. The equivalence point is reached after adding 25.0 mL NaOH.

State whether the pH at equivalence would be less than 7, equal to 7, or greater than 7.

1b
1 point

Explain your answer by identifying the species present at equivalence.

1c
1 point

At what volume of NaOH does the half-equivalence point occur?

1d
1 point

At half-equivalence, state the relationship between pH and pKa.

2a
1 point

A titration has an equivalence-point pH of 8.8.

Indicator

pKa

Methyl orange

3.7

Bromothymol blue

7.0

Phenolphthalein

9.3

Which indicator is most suitable? Justify your choice.

2b
2 points

The chemist also performs a strong acid–weak base titration.

Using the indicator table in part (a), choose the most suitable indicator for this new titration and justify your choice.

1a
1 point

Potassium sorbate, KC6H7O2 (molar mass 150 g/mol) is commonly added to diet soft drinks as a preservative. A stock solution of KC6H7O2(aq) of known concentration must be prepared. A student titrates 45.00 mL of the stock solution with 1.25 M HCl(aq) using both an indicator and a pH meter. The value of Ka for sorbic acid, HC6H7O2, is 1.7 × 10−5.

Write the net-ionic equation for the reaction between KC6H7O2(aq) and HCl(aq).

1b
2 points

A total of 29.95 mL of 1.25 M HCl(aq) is required to reach the equivalence point. Calculate [KC6H7O2] in the stock solution.

1c
2 points

The pH at the equivalence point of the titration is measured to be 2.54. Which of the following indicators would be the best choice for determining the end point of the titration? Justify your answer.

Indicator

pKa

Phenolphthalein

9.3

Bromothymol blue

7.0

Methyl red

5.0

Thymol blue

2.0

Methyl violet

0.80

1d
1 point

Calculate the pH at the half-equivalence

1e
3 points

The initial pH and the equivalence point are plotted on the graph below. Accurately sketch the titration curve on the graph below. Mark the position of the half-equivalence point on the curve with an X.

q3e-june-2015---ap-chemistry
1f
1 point

The pH of the soft drink is 3.37 after the addition of the KC6H7O2(aq). Which species, HC6H7O2 or C6H7O2, has a higher concentration in the soft drink? Justify your answer.

2a
1 point

Answer the following questions relating to Fe and its ions, Fe2+ and Fe3+.

Write the ground-state electron configuration of the Fe2+ ion.

2b
1 point

Ion

Ionic Radius (pm)

Fe2+

92

Fe3+

79

The radii of the ions are given in the table above. Using principles of atomic structure, explain why the radius of the Fe2+ ion is larger than the radius of the Fe3+ ion.

2c
1 point

Fe3+ ions interact more strongly with water molecules in aqueous solution than Fe2+ ions do.

Give one reason for this stronger interaction, and justify your answer using Coulomb’s law.

2d
1 point

A student obtains a solution that contains an unknown concentration of Fe2+ (aq). To determine the concentration of Fe2+ (aq) in the solution, the student titrates a sample of the solution with MnO4 (aq), which converts Fe2+ (aq) to Fe3+ (aq) , as represented by the following equation.

5 Fe2+ (aq) + MnO4 (aq) + 8 H+ (aq) →  5 Fe3+ (aq) + Mn2+ (aq) + 4H2O(l)

Write the balanced equation for the half-reaction for the oxidation of Fe2+ (aq) to Fe3+ (aq) .

2e
2 points

The student titrates a 10.0 mL sample of the Fe2+ (aq) solution . Calculate the value of [Fe2+] in the solution if it takes 17.48 mL of added 0.0350 M KMnO4 (aq) to reach the equivalence point of the titration.

2f
1 point

To deliver the 10.0 mL sample of the Fe2+ (aq) solution in part (e), the student has the choice of using one of the pieces of glassware listed below.

  • 25 mL buret 

  • 25 mL beaker

  • 25 mL graduated cylinder

  • 25 mL volumetric flask

Explain why the 25 mL volumetric flask would be a poor choice to use for delivering the required volume of the Fe2+ (aq) solution.

2g
1 point

In a separate experiment, the student is given a sample of powdered Fe (s) that contains an inert impurity. The student uses a procedure to oxidize the Fe(s) in the sample to Fe2O3 (s) . The student collects the following data during the experiment.

Mass of Fe (s) with inert impurity

6.724 g

Mass of Fe2O3 (s) produced

7.531 g

Calculate the number of moles of Fe in the Fe2O3(s) produced.

2h
1 point

Calculate the percent by mass of Fe in the original sample of powdered Fe (s) with the inert impurity.

2i
1 point

If the oxidation of the Fe (s) in the original sample was incomplete so that some of the 7 .531 g of product was FeO (s) instead of Fe2O3, would the calculated mass percent of Fe (s) in the original sample be higher, lower, or the same as the actual mass percent of Fe (s)? Justify your answer.

3a
1 point

A student performs a titration of 50.0 mL of 0.100 M acetic acid (CH3COOH) with 0.100 M NaOH. The titration curve is recorded using a pH meter.

The Ka of acetic acid is 1.76 x 10-5.

Write the net ionic equation for the reaction.

3b
2 points

i) Describe what occurs at the equivalence point during the titration of acetic acid with sodium hydroxide.

i) Explain why the pH at the equivalence point is greater than 7.

3c
1 point

Identify the pH at the half-equivalence point and explain how it relates to the pKa of acetic acid.

4a
1 point
q3a_medium_calculations-involving-acids--bases_ib-dp-chem_hl

An aqueous solution of acetic acid (CH3COOH) is titrated with 0.150 M sodium hydroxide (NaOH).

Label the half-equivalence point on the graph by marking it with an "X."

4b
2 points

The titration reaches the equivalence point when 25.0 mL of acetic acid has reacted with an equal number of moles of NaOH.

The Ka of acetic acid is 1.75 x 10−5

(i) Explain why the pH at the half-equivalence point is numerically equal to the pKa of acetic acid.

(ii) Calculate the pH at the half-equivalence point.

4c
1 point

After completing the titration, the student wants to verify their experimental results by calculating the volume of NaOH required to reach the first equivalence point.

Determine the volume of 0.150 M NaOH needed to fully neutralize 50.0 mL of 0.100 M acetic acid.

5a
1 point
q5c_medium_calculations-involving-acids--bases_ib-dp-chem_hl

Volume of HCl (cm3)

A student performs a titration using a 0.10 M ammonia, NH3 (aq), and a 0.10 M hydrochloric acid, HCl (aq).

Write the equation for the overall reaction that is occurring.

5b
2 points

Mark on the curve the point at which the pOH is equal to pKb of the weak base and deduce the pKb of the acid.

5c
1 point

A student repeats the titration using 0.100 M acetic acid (CH₃COOH), which has a pKa value of 4.76. The resulting titration curve is shown below.

Explain why accurately determining the equivalence point for this titration is more challenging compared to a strong acid-strong base titration.

1a
1 point

A student reacts 0.300 g of methyl salicylate (C8H8O3) with a stoichiometric amount of a strong base. This product is then acidified to produce salicylic acid crystals (HC7H5O3).

For every 1 mole of C8H8O3 (molar mass 152.15 g/mol) reactant used, 1 mole of salicylic acid crystals (HC7H5O3, molar mass 138.12 g/mol) is produced. Calculate the maximum mass, in grams, of HC7H5O3 that could be produced in this reaction.

1b
1 point

As part of the experimental procedure to purify the HC7H5O3 crystals after the reaction is complete, the crystals are filtered from the reaction mixture, rinsed with distilled water, and dried. Some physical properties of HC7H5O3 are given in the following table.

Properties of Salicylic Acid (HC7H5O3)

 Melting point

159°C

Solubility in H2O at 25°C  

2.2 g/L

 Specific heat capacity

1.17 J/(g·°C)

 Heat of fusion

27.1 kJ/mol

The student’s experiment results in an 87% yield of dry HC7H5O3. The student suggests that some of the HC7H5O3 crystals dissolved in the distilled water during the rinsing step. Is the student’s claim consistent with the calculated percent yield value? Justify your answer.

1c
2 points

Given the physical properties in the table, calculate the quantity of heat that must be absorbed to increase the temperature of a 0.105 g sample of dry HC7H5O3 (molar mass 138.12 g / mol) crystals from 25° C to the melting point of 159° C and melt the crystals completely.

1d
1 point

The structures and melting points for methyl salicylate and salicylic acid are shown.

q1c-june-2022---ap-chemistry

The same three types of intermolecular forces (London dispersion forces, dipole-dipole interactions, and hydrogen bonding) exist among molecules of each substance. Explain why the melting point of salicylic acid is higher than that of methyl salicylate.

1e
1 point

The student titrates 20.0  mL of 0.0100 M  HC7H5O3(aq) with 0.0200 M  NaOH, using a probe to monitor the pH of the solution. The data are plotted producing the following titration curve.

q1d-june-2022---ap-chemistry

Using the information in the graph, estimate the pKa  of HC7H5O3.                                 

1f
1 point

When the pH of the titration mixture is 4.00, is there a higher concentration of the weak acid, HC7H5O3, or its conjugate base, C7H5O3, in the flask? Justify your answer.

1g
1 point

The student researches benzoic acid (HC7H5O2) and finds that it has similar properties to salicylic acid (HC7H5O3). The Ka  for benzoic acid is 6.3 × 10−5. Calculate the value of pKa  for benzoic acid.

1h
2 points

The student performs a second titration, this time titrating 20.0 mL of a 0.0100 M benzoic acid solution with 0.0200 M NaOH. Sketch the curve that would result from this titration of benzoic acid on the following graph, which already shows the original curve from the titration of 20.0 mL of 0.0100 M salicylic acid. The initial pH of the benzoic acid solution is 3.11.

q1h-june-2022---ap-chemistry
2a
1 point

A 50.0 mL sample of 0.100 M phosphoric acid (H3PO4) is titrated with 0.100 M NaOH. The first, second, and third equivalence points occur at pH values of approximately 4.7, 9.8, and 12.0, respectively. The student must select an appropriate indicator to detect the first equivalence point and is given the indicators listed in the table.

Indicator

pKa

pH range

Methyl red

5.0

4.2 - 6.3

Bromothymol blue

7.0

6.0 - 7.6

Alizarin yellow

11.0

10.1 - 12.0

Write the balanced chemical equation for the reaction occurring at the first equivalence point.

2b
1 point

Identify the most appropriate indicator for detecting the first equivalence point and justify your choice.

2c
1 point

Explain why bromothymol blue would not be a suitable indicator for detecting any of the equivalence points in this titration.

2d
1 point

Explain why the solution acts as a buffer at the first half-equivalence point of the titration.

3a
2 points

Sketch a titration curve for the reaction of 50.0 mL of 0.100 M HNO₃ (aq) with 25.0 mL of 0.100 M NH₃ (aq). Label the following points:

  • The buffer region

  • The equivalence point

18-1-hl-sq-q2-q
3b
1 point

NH3​ (aq) + HNO3 ​(aq) → NH4+ ​(aq) + NO3​(aq)

The reaction between ammonia and nitric acid is represented by the equation above.

Using the equation to explain why the pH at the equivalence point is less than 7.

3c
1 point

The student must select an appropriate indicator for this titration. The table shows the pKa values and pH transition ranges for three indicators.

Indicator

pKa

pH transition Range

Methyl red

5.0

4.2 - 6.3

Bromothymol blue

7.0

6.0 - 7.6

Phenolphthalein

9.3

8.3 - 10.0

Based on the data, identify the most suitable indicator for this titration and justify your choice.

4a
1 point

A 50.0 mL sample of 0.150 M benzoic acid (C6H5COOH) is titrated with 0.100 M NaOH. The pKa of C6H5COOH is 4.20.

Write the balanced chemical equation for the reaction that occurs during the titration.

4b
1 point

Calculate the volume of NaOH required to reach equivalence point.

4c
2 points

Calculate the pH at equivalence point.

Assume that only benzoate ions (C6H5COO⁻) are present at equivalence, and the Kb of C6H5COO⁻ can be determined using the relationship Kw = Ka × Kb.