Chrominfo

Assay of calcium carbonate

Assay of magnesium sulphate

Learn about the assay of magnesium sulphate through a laboratory experiment or practical.

Aim:

To determine the percentage purity of magnesium sulphate using standard 0.1 N EDTA (Direct titration).

Requirements:

Glasswares: Burette, burette stand, conical flask, volumetric pipette, beaker, volumetric flask, funnel, glass rod, and wash bottle, etc.

Chemicals: Magnesium sulphate heptahydrate (MgSO4), disodium edetate (EDTA), ammonia (NH3), calcium chloride (CaCl2), ammonium chloride (NH4Cl), and solochrome black-T indicator or mordant black II, etc.

Reaction Involved:

The assay of MgSO4.7H2O is based upon the reactions designated by the following equations:

Mg2⁺ + [H2X]^2‑→ [MgX]‑ + 2H⁺

Preparation and standardization of 0.05 M EDTA solution:

Click here to get the procedure.

Preparation of strong ammonia-ammonium chloride solution:

Click here to get the procedure.

Titration procedure:

All glassware should be cleaned and dried according to standard laboratory procedures.
Before filling the burette for the titration, rinse it with distilled water and then pre-rinse it with a portion of the titrant solution. Pre-rinsing is required to make sure that all solution in the burette is the desired solution, not a contaminated or diluted solution.
Take the unknown stock solution of titrant in a clean and dry beaker then fill the burette using the funnel.
Remove air bubbles from the burette and adjust the reading to zero.
Take 0.3 gm of magnesium sulphate and pour it into a conical flask, and dissolve in 50 ml of warm water.
Using a pipette, add 10.00 ml of strong ammonia-ammonium chloride solution.
Then, as an indicator, add 2-3 drops of mordant black II mixture and properly mix it.
Titrate the sample solution with standardized 0.05 disodium edetate until the endpoint is reached.
The actual endpoint is indicates by the pink color is discharged from the blue.
Properly record the readings of the burette.
To get accurate results, repeat the titration three times.
Take their mean and calculate the percentage purity of magnesium sulphate.
Each ml of 0.05 M disodium ethylene diamine tetracetate is equivalent to 0.00602 g of MgSO4.

Observation table:

Sr. No.	Content in conical flask	Burette reading		Volume of titrant used (ml)
Sr. No.	Content in conical flask	Initial	Final	Volume of titrant used (ml)
1
2
3
				Mean:

Result:

The percentage purity of the magnesium sulphate (MgSO4) sample was found to be_____.

You may also like this

Assay of boric acid

Assay of sodium bicarbonate

Assay of magnesium sulphate

Thursday, December 30, 2021

Assay of calcium carbonate

Learn about the assay of calcium carbonate through a laboratory experiment or practical.

Aim:

To determine the percentage purity of calcium carbonate using standard 0.1 N EDTA (Direct titration).

Reference: Indian Pharmacopeia (IP)

Requirements:

Glasswares: Burette, burette stand, conical flask, volumetric pipette, beaker, volumetric flask, funnel, glass rod, and wash bottle, etc.

Chemicals: Calcium carbonate (CaCO3), hydrochloric acid (HCl), disodium edetate (EDTA), and calcon indicator mixture, etc.

Preparation of dilute hydrochloric acid:

Preparation of 0.05 M EDTA solution:

Click here to get the procedure.

Preparation of sodium hydroxide solution:

Take properly weighed 10.00 gm of oxalic acid and dissolve in 50 ml of distilled water in a volumetric flask, and properly mix it. Once it has completely dissolved, make up the volume to 100 ml.

Titration procedure:

All glassware should be cleaned and dried according to standard laboratory procedures.
Before filling the burette for the titration, rinse it with distilled water and then pre-rinse it with a portion of the titrant solution. Pre-rinsing is required to make sure that all solution in the burette is the desired solution, not a contaminated or diluted solution.
Take the unknown stock solution of titrant in a clean and dry beaker then fill the burette using the funnel.
Remove air bubbles from the burette and adjust the reading to zero.
Take properly weighed 01.00 gm of calcium carbonate and dissolved in 10.00 ml water and 03.00 ml dilute hydrochloric acid.
Boil for 10 minutes, then cool and dilute with water to 50.00 ml.
Titrate with 0.05 M EDTA to within a few ml of the predicted end-point, then add 08.00 ml of NaOH solution and 100 mg of calcon mixture as an indicator, and keep titrating until the color of the solution changes from pink to a blue.
To get accurate results, repeat the titration three times.
Properly record the readings of the burette.
Take their mean and calculate the % purity of calcium carbonate.

Observation table:

Sr. No.	Content in conical flask	Burette reading		Volume of titrant used (ml)
Sr. No.	Content in conical flask	Initial	Final	Volume of titrant used (ml)
1
2
3
				Mean:

Calculation:

Each ml of 0.05M EDTA is equivalent to 0.005004 g of calcium carbonate.

% Assay = V x M x F / 0.05 x W x 100 / (100-LOD)

Where,

V is blank reading- sample reading

M is the molarity of 0.05M disodium Edetate

F is factor

W is the sample weight

Result:

The percentage purity of the calcium carbonate (CaCO3) sample was found to be_____.

You may also like this

Assay of boric acid

Assay of sodium bicarbonate

Assay of calcium carbonate

Assay of boric acid

Learn about the assay of boric acid through a laboratory experiment or practical.

Aim:

To determine the percentage purity (assay) of boric acid in a given sample using standard 0.1 N NaOH.

Reference: Indian Pharmacopeia (IP)

Principle of assay of boric acid:

The alkalimetry method is used to perform an assay of boric acid. Since it is such a weak acid, it cannot be accurately titrated with a strong base. It behaves like a strong monobasic acid when dissolved in a mixture of water and glycerol, and it may then be titrated with a standard alkali solution using phenolphthalein as an indicator.

Requirements:

Glasswares: Burette, burette stand, conical flask, volumetric pipette, beaker, volumetric flask, funnel, glass rod, and wash bottle, etc.

Chemicals: Boric acid (H3BO3), glycerol (C3H8O), phenolphthalein indicator, sodium hydroxide (NaOH), and oxalic acid (C2H2O4), etc.

Preparation of 1N NaOH solution:

Take properly weighed 04.00 gm of sodium hydroxide and dissolve in 50 ml of distilled water in a volumetric flask, and properly mix it. Once it has completely dissolved, make up the volume to 100 ml.

Preparation of 1N oxalic acid solution:

Take properly weighed 06.30 gm of oxalic acid and dissolve in 50 ml of distilled water in a volumetric flask, and properly mix it. Once it has completely dissolved, make up the volume to 100 ml.

Titration procedure:

All glassware should be cleaned and dried according to standard laboratory procedures.
Before filling the burette for the titration, rinse it with distilled water and then pre-rinse it with a portion of the titrant solution. Pre-rinsing is required to make sure that all solution in the burette is the desired solution, not a contaminated or diluted solution.
Take the unknown stock solution of titrant in a clean and dry beaker then fill the burette using the funnel.
Remove air bubbles from the burette and adjust the reading to zero.

For standardization of sodium hydroxide:

Pipette out 10.00 ml of 0.1 N oxalic acid into a conical flask and add 1-2 drops of phenolphthalein indicator.
Titrate the solution against the NaOH solution until it turns pink in color.
Repeat the titration to get concurrent values.

For assay:

Take properly weighed 02.00 gm and dissolved in 50.00 ml water and 100 ml glycerol solution previously neutralized to phenolphthalein solution.
Add 2-3 drops of phenolphthalein indicator.
Titrate the sample solution with 1N NaOH until the endpoint is reached.
The actual endpoint of the titration is indicated by a faint pink color.
Properly record the readings of the burette.
To get accurate results, repeat the titration three times.
Take their mean and calculate the % purity of boric acid.

Observation table:

Sr. No.	Content in conical flask	Burette reading		Volume of titrant used (ml)
Sr. No.	Content in conical flask	Initial	Final	Volume of titrant used (ml)
1
2
3
				Mean:

Calculation:

I.P. factor: Each ml of 1 N NaOH is equivalent to 0.016183 g of H3BO3.

Formula:

Percent purity of H3BO3= Volume of NaOH x I.P. Factor x 100 x N of NaOH (actual) / weight of H3BO3 x N of NaOH (exp)

Result:

The percentage purity of the boric acid (H3BO3) sample was found to be_____.

Frequently Asked Questions (FAQ):

Why Glycerin is used in the assay of boric acid?

Glycerin is used in the assay of boric acid because boric acid is a weak monobasic acid that does not easily react with sodium hydroxide because of its low tendency to give hydrogen ions in its solution. When glycerol and boric acid are combined, the boric acid becomes more acidic and can readily act as a monobasic acid.

Assay of boric acid is done by which titration?

The assay of boric acid is performed using acid-base titration (alkalimetry), in which acidic substance-using a standard base.

You may also like this

Assay of magnesium sulphate

Assay of sodium bicarbonate