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TITRATION
EQUATIONS:NaOH + HCl ⟶ NaCl + H2O
2KOH + H2SO4 ⟶ K2SO4 + 2H2O
KOH + HNO3 ⟶ KNO3 + H2O
2NaOH + H2C204.2H20 ⟶ Na2C204 + 4H20
2KOH + H2C204.2H20 ⟶ 2C204 + 4H20
2HCI + Na2CO3 ⟶ 2NaCI + CO2 + H2O
H2SO4 + K2CO3 ⟶ K2SO4 + CO2 + 2H20
2HNO3 + K2CO3 ⟶ 2KNO3 + CO2 + H2O
H2SO4 + Na2CO3 ⟶ Na2SO4 + CO2 + H2O
2KMn04 + 3H2SO4 ⟶ K2SO4 + 3H20 + 2MnSO4 + 5[O]
10FeSO4 + 5H2SO4 + 5[0] ⟶ 5Fe2(SO4)3 + 5H20
2KMn04 + 10FeSO4 + 8H2SO4 ⟶ K2SO4 + 2MnSO4 + 5Fe2(SO4)3 + 8H20
2KMn04 + 3H2SO4 ⟶ K2SO4 + 3H20 + 2MnSO4 + 5[O]
5H2C2O4 + 5[0] ⟶ 10CO2 + 5H20
2KMn04 + 5H2C2O4 + 3H2SO4 ⟶ K2SO4 + 2MnSO4 + 10CO2 + 8H20
IONIC EQUATION FOR ACID — BASE
Na+ + OH- + H+ + Cl- ⟶ Na+ + Cl- + H2O
2K+ + 20H- + 2H+ + SO42- ⟶ 2K+ + SO42- + 2H20
K+ + OH- + H+ + NO3- ⟶ K+ + NO3- + H20
2Na+ + 20H- + 2H+ + C2042- ⟶ 2Na+ + C2042- + 2H20
2K+ + OH- + 2H+ + C2042- ⟶ 2K+ + C2042- + 2H20
2H+ + 2Cl- + 2Na+ + CO32- ⟶ 2Na+ + 2Cl- + CO2 + H2O
2H+ + SO42- + 2K+ + CO32- ⟶ 2K+ + SO42- + CO2 + H2O
2H+ + 2NO3- + 2K+ + CO32- ⟶ 2K+ + 2NO3- + CO2 + H20
2H+ + SO42- + 2Na+ + CO32- ⟶ 2Na+ + SO42- + CO2 + H2O
THEORY
FOR ACID-BASE TITRATION:
Titration is a process in which the fixed volume of a solution taken by means of pipette into conical flask is compared with the volume of solution added from burette upto end point which is obtained by colour change. The purpose of titration is to determine the unknown strength of a solution.
Base is a substance which gives OH- ion in aqueous solution. When an acid solution reacts completely with base solution or vice versa, a salt is formed.
Neutralization: In acid-base reaction H+ ion from an acid and OH- ion from a base form H2O, salt is also formed process is called neutralization. This is indicated by end point and is observe by suitable indicator those having different colors in different medium.
Strong acid and strong base ionize completely in aqueous solution while weak acid and weak base ionize only partially in aqueous solution, these form acidic and basic salts which hydrolyse to change the pH.
Na2CO3 + H2O ⟶ NaOH + H2CO3
(Basic salt) + (water) (Strong base) (Weak acid)
where Basic (pH > 7)
FOR REDOX TITRATION:
Titration is a process in which the fixed volume of a solution taken by means of pipette Into conical flask is compared with the volume of solution added from burette upto end point which is obtained by colors change. The purpose of titration is to determine the unknown strength of a solution using standard solution.
Redox Titration: The type of titration in which one reactant in oxidized and other reduced are know as redox titration.
Oxidation is a process in which reducing Agent loses electron and absorbs oxygen, so the oxidation number increases.
Fe2+ ⟶ Fe3+ + e-
2FeSO4 + H2SO4 + [0] ⟶ Fe2(SO4)3 + H2O
Reduction is a process in which oxidizing agent gain electron and loses oxygen, so oxidation number decreases Mn7+ + 5e- ⟶ Mn2+
2KMnO4 + H2SO4 ⟶ K2SO4 2MnSO4 + 3H20 + 5[O]
Oxidizing strength of KMnO4 increase in the presence of H2SO4, so H2SO4 is required in redox titration. KMnO4 is coloured substance so it acts as indicator, therefore no external indicator is required.Reaction between KMnO4 and oxalic acid is very slow because oxalic acid is a covalent organic compound. So the Titration flask is heated to about 60 — 70°C before adding KMnO4 from the burette.
PROCEDURE:
Strong Base Vs Stron Acid OR Strong Base Vs Weak Acid
1. Wash burette, pipette and conical flask with water.
2. Rinse burette with base and pipette with acid.
3. Do not rinse the conical flask.
4. Fill the burette with base upto Zero mark.
5. Pipette out 10 cm3 of acid into the conical flask.
6. Add one or two drops of phenolphthalein as indicator.
7. Titrate the base in the burette with the acid in conical flask. The burette solution is added drop by drop into the conical flask.
8. Shake the flask after each addition, The end point is indicated by colour change from colourless to light pink.
9. Note the end point.
10. wash the conical flask with water and repeats the same process for at least three times to obtain two similar readings.
Strong Acid Vs Weak Base
1. Wash burette, pipette and conical flask with water.
2. Rinse burette with acid and pipette with base solution.
3. Do not rinse the conical flask.
4. Fill the burette with acid upto Zero mark.
5. Pipette out 10 cm3 of base into the conical flask.
6. Add one or two drops of methyl orange as indicator.
7. Titrate the acid in the burette with the base in conical flask. The burette solution is added drop by drop into the conical flask.
8. Shake the flask after each addition, The end point is indicated by colour change from yellow to light pink.
9. Note the end point.
10. Wash the conical flask with water and repeat the same process for at least three times to obtain two similar readings.
Redox Titration
1. Wash all the apparatus with water.
2. Rinse burette with KMnO4 and pipette with reducing agent.
3. Do not rinse the conical flask.
4. Fill the burette with base upto Zero mark.
5. Pipette out 10 cm3 of given reducing agent into the conical flask.
6. Add one test tube of dilute H2SO4 (In case of oxalic acid as a reducing agent titration flask is heated to about 60 - 70°C before titration).
7. Titrate KMnO4 in the burette with the reducing agent in conical flask. The burette solution is added drop by drop into the conical flask.
8. Shake the flask after each addition, the end point is indicated by colour change from colourless to light pink.
9. Note the end point.
10. Wash the conical flask with water repeat the same process for at least three times to obtain two similar readings.
OBSERVATION:
| S.NO. | Initial reading | Final reading | Difference | Concordant reading |
|---|---|---|---|---|
| 1. | cm3 | cm3 | cm3 | cm3 |
| 2. | cm3 | cm3 | cm3 | |
| 3. | cm3 | cm3 | cm3 |
- Solution in burette = ______ (Strong Acid Or Strong Base)
- Solution in conical flask = ________ (Weak Acid Or Weak Base)
- Indicator used = _______ (e.g Phenophthalein for Strong Base)
- Normality of standard solution = N1 = ___ N
- Volume of standard solution = V1 = 10 ml
- Normality of solution of unknown strength = N2 = ?
- Volume of solution of unknown strength = V2 = ?
CALCULATION:
Standard solution Vs Solution of unknown strength
N1V1 = N2V2
Equivalent mass = Molecular mass / Acidity or Basicity or change in oxidation state Amount = Normality (N2) x equivalent mass x volume of solution in cm3 / 1000
RESULT:
- Normality of given ________ solution = ______ N
- Amount of ______ in the given solution = gms / ___ dm3 or ____ cm3
Acidity Of Base:
| Base | Acidity | Equivalent mass |
|---|---|---|
| NaOH | 1 | 40 |
| KOH | 1 | 56 |
| Na2CO3 | 2 | 53 |
| K2CO3 | 2 | 69 |
Basicity Of Acid
| Acid | Basicity | Equivalent mass |
|---|---|---|
| HCl | 1 | 36.5 |
| H2SO4 | 2 | 49 |
| HNO3 | 1 | 63 |
| C2H204.2H20 | 2 | 63 |
Oxidizing Agent
| Oxidizing agent | No. of electron gained | Equivalent mass |
|---|---|---|
| KMnO4 | 5 | 31.6 |
Reducing Agent
| Reducing Agent | No. of electron lost | Equivalent mass |
|---|---|---|
| FeSO4.7H20 | 1 | 278 |
| FeSO4.(NH4)2SO4.6H20 | 1 | 392 |
| H2C204.2H20 | 2 | 63 |
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