Class 12 volumetric analysis Full Note with important questions

Volumetric analysis

Volumetric analysis, also known as titrimetry, is a quantitative analytical method used to determine the concentration of a solution by reacting it with a standardized solution of known concentration. The process involves measuring the volume of the solution required to react completely with a known volume of the standardized solution, also called the titrant.

The most common types of titrations involve acid-base reactions, oxidation-reduction reactions, and complexometric reactions. In acid-base titrations, the pH of the solution changes as the titrant is added, and an indicator is used to signal the end point of the reaction. In oxidation-reduction titrations, a redox indicator or a potentiometer is used to detect the end point of the reaction. In complexometric titrations, a chelating agent is added to form a complex with the analyte, and an indicator is used to signal the end point.

Volumetric analysis is widely used in many fields, including chemistry, biology, medicine, and environmental science. It is an accurate and precise method for determining the concentration of a solution, and it can be used to analyze both pure substances and complex mixtures

Gravimetric analysis is a quantitative analytical method used to determine the amount of a substance present in a sample by measuring its mass. The method involves isolating the substance of interest by precipitation or volatilization and then weighing the precipitate or residue.

The basic steps of a gravimetric analysis include:

Sample preparation: The sample is collected, treated, and weighed accurately.
Precipitation: The substance of interest is converted into a solid, insoluble form by adding a precipitating agent.
Filtration: The precipitate is separated from the solution by filtration.
Washing: The precipitate is washed to remove any impurities or soluble salts that may be present.
Drying: The precipitate is dried at a suitable temperature to remove any moisture.
Weighing: The dried precipitate is weighed accurately.
Calculation: The amount of substance present in the original sample is calculated based on the weight of the precipitate.

Gravimetric analysis is a highly accurate and precise method for determining the amount of a substance present in a sample. It is widely used in many fields, including chemistry, environmental science, and pharmaceuticals, to analyze both pure substances and complex mixtures

Volumetric Analysis Chemistry Questions with Solutions

Q1: How does Potassium permanganate act as a self indicator?

Answer: A self indicator is a substance that along with itself participating in the reaction, indicates the end point of the reaction. Potassium permanganate is a violet-coloured solution. It acts as a strong oxidizing agent and thus, turns colourless when added to oxalic acid solution in the acidic medium. However, at the end point, it gives a faint pink colour in the acidic solution.

Q2. In the titration of Potassium permanganate with Oxalic acid, why is the oxalic acid solution warmed in the beginning?

Answer: In order to speed up the reaction, the oxalic acid solution is heated up to 50-60 oC. In the beginning of the reaction, manganous sulphate is formed which catalyses the reduction of KMnO4. This leads to the slowed rate of the reaction. The reaction gets auto-catalysed as it proceeds forward.

Q3. How is the strength of a solution calculated?

Answer: The strength of a solution is determined by calculating the amount of solute in grams present in 1 Litre of the solution. The unit of strength is g L-1.

Therefore, Strength = Mass of Solute (g) / Volume of solution (L)

Strength of a solution can also be calculated as:

Strength = Molarity x Molar mass

Q4. How many grams of NaOH is required to make 250 cm3 solution of 0.025 M NaOH solution?

Answer: Given: 0.025 M NaOH solution which means that 0.025 moles of NaOH are present in 1 L of solution.

1000 cm3 0.025 M NaOH solution contains NaOH = 0.025 mol.

250 cm3 0.025 M NaOH solution contains NaOH = (0.025/1000) x 250 mol = 0.00625 mol

The molar mass of NaOH is 40 g/mol.

Hence, the mass of 0.00625 moles of NaOH = 0.00625 x 40 g = 0.25 g

Q5. List some limitations of the volumetric analysis.

Answer: Some of the major limitations of the volumetric analysis are given below:

Large amounts of chemicals are used and discarded.
This method has limited accuracy.
Failure in observing the end point may lead to disturbed calculations.
Natural factors such as temperature, pressure and humidity may affect the titration reaction as the titration is carried out in an open vessel/flask.
Indicators are required to detect the end point of the reaction.
Liquid-phase reactions for the titration are required.

Q6. What volume of concentrated sulphuric acid is required to make 5 litre of 0.5 M H2SO4 solution? The concentrated sulphuric acid is 98% H2SO4 by mass and its density is 1.84 g cm-3.

Answer: Given 98% H2SO4 by mass means 98 g H2SO4 is present in 100 g of solution.

From the given density, the volume of the concentrated H2SO4 is calculated as:

Volume = mass/ density

Hence, volume of the concentrated H2SO4 is 100 / 1.84 cm3 = 54.35 cm3 = 0.5435 L

The molar mass of H2SO4 is 98 g/mol i,e. 98 g H2SO4 equals 1 mole of H2SO4.

Hence, the molarity of the given concentrated H2SO4 is 1 mol / 0.5435 L = 18.4 M

Now, to determine the required amount of concentrated H2SO4, the molarity formula is applied as: M1V1 = M2V2

Where, M1 = Molarity of concentrated H2SO4 solution

V1 = Required volume of concentrated H2SO4 solution

M2 = 0.5 M

V2 = 5 L

Hence, 18.4 M x V1 = 5 L x 0.5 M

V1 = 0.136 L = 136 cm3

Thus, the volume of concentrated sulphuric acid required to make 5 litre of 0.5 M H2SO4 solution is 136 cm3.

Q7. What is the specific name that is given to potassium permanganate solution?

Answer: The potassium permanganate solution is also known as Baeyer’s Reagent.

Q8. Why in permanganate titrations the burette with the pinch-cock regulator not used?

Answer: This is because the permanganate solution attacks the rubber.

Q9. Would you consider the upper or lower meniscus of potassium permanganate solution in the burette?

Answer: As the potassium permanganate solution is a deeply coloured solution, the upper meniscus of the burette is considered.

Q10. Why HNO3 or HCl are not used in permanganate titrations?

Answer: HNO3 is not used as it is a stronger oxidizing agent. However, HCl reacts with KMnO4 and disturbs the reaction.

Q11. What are primary and secondary standards?

Answer: The primary standard substances are stable, pure, readily soluble in most of the solutions and remain unaffected by the presence of moisture and air. The solutions of these substances remain as such for a number of days. While, the secondary standard substances do not possess the aforementioned characteristics.

Q12. What is the equivalent mass of KMnO4 in acidic medium?

Answer: KMnO4 acts as an oxidizing agent and loses 5 electrons per molecule during the reaction. Hence, the equivalent mass of KMnO4 in acidic medium is mol. Mass / Total positive valency. The equivalent mass of KMnO4 = 158 / 5 = 31.6 g.

Q13. What is the Basicity of H3PO4 solution?

Answer: Basicity of an acid is the total number of displaceable H+ ions present in 1 molecule of the acid. Hence, the Basicity of H3PO4 solution is 3.

Q14. Write the principle of Volumetric analysis.

Answer: The principle of Volumetric analysis is based on the fact that the unknown concentration of the known solution can be determined by titrating it with the known volume of another solution with known concentration.

Q15. Are the equivalence point and end point the same?

Answer: The equivalence point is the point when the reactants just react completely. It does not bring any change in the appearance of the colour of the solution. However, an end point is achieved right after the equivalence point, and the excess of the titrant added gives the end colour of the reaction. Hence, the equivalence point and endpoint are not the same.