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Karl Fischer Titration
- 1. Welcome
- 2. Group Members 1.Afsana Afrin Urmee ( ID: 2016-3-70-010) 2.Shukla Sarkar ( ID: 2016-3-70-011) 3.A.B.M. Manzurul Hassan (ID: 2016-3-70- 012)
- 4. Introduction What is Karl Fischer Method? What are the advantages and disadvantages of Karl Fischer method? What is the procedure of doing Karl fisher method? What are the applications of Karl Fischer method?
- 5. c c 1 2 3 Classic titration method Uses coulometric or volumetric titration Determine trace amounts of water in a sample That To What is Karl Fischer Method ?
- 6. Present Day What is Karl Fischer Method ? c c Invented By Automatized Karl-Fischer titrator. Karl Fischer (1935)
- 7. I2 + SO2 + 2H2O ―›2HI + H2SO4 c Bunsen Reaction Principle 1 CH3OH + SO2 + RN ―› [RNH]SO3CH3 [RNH]SO3CH3 + I2 + H2O + 2RN ―› [RNH]SO4CH3+ 2 [RNH]I 2
- 8. c Principle Since the , Amount of water ≡ Amount of I2 Amount of consumed I2 Amount of water
- 11. Difference Designed for titration of Liquids & Gases only. I2 is generated at an electrode. Water levels in the sample: 0.001- 0.1% H2O Designed for titration of Solids, liquids & gases. I2 is included with the reagents. Water levels in the sample: 0.1-100% H2O Coulometric KFT Volumetric KFT
- 12. Difference Poor system flexibility. No option for Temperature Modification. Co-solvents are limited. Good system flexibility. Modification of temperature can be possible . Modified solvent system. Coulometric KFT Volumetric KFT
- 13. Coulometric KFT Two Types 1 2 Fritted Cell coulometric KFT A diaphragm separates the anode from the cathode to form generator electrode that prevent iodine reduction. Frittless Cell coulometric KFT A Combination of factors without frit, makes it nearly impossible for iodine to get reduced. c c
- 14. Volumetric KFT c c Two component system • Higher titration speed • Greater accuracy • Higher buffer capacity • Lower solvent capacity, more costly One component system • Unlimited water capacity • Easier to handle • Less expensive Two Types 1 2
- 15. Bipotentiometric Titration Bipotentiometric titration is simply monitoring the extent of reaction by measuring changes in electrical conductivity of the reaction solution. Both Coulometric and volumetric method use bipotentiometric titration to measure the amount of I2 consumed by the water.
- 16. Bipotentiometric Titration Measuring I2 The second reaction in the KF titration is a redox reaction: [RNH]SO3CH3+I2+H2O+2RN [RNH]SO4CH3+2[RNH]I Sulphur oxidized from alkylsulfite to alkylsulphate: SO3CH3 -2 SO4CH3 -2+2e- (Oxidation number increased +4 to +6) Iodine is reduced: I2+2e- 2I- (E0 = 0.54 V)
- 17. Bipotentiometric Titration Measuring I2 The reduction of iodine consumes electrons generated by the oxidation of Sulphur, which changes the electrical potential of the system. The changes in potential is detected by an electrode ( a double platinum electrode).
- 18. The karl Fischer method for the determinations of water is used for prednisolone sodium phosphate as described below: Materials required: • Karl Fischer reagent: 100 ml • Prednisolone sodium phosphate: 0.2 g • Anhydrous methanol: 20 ml
- 19. The Karl Fischer method for the determination of water is used for prednisolone sodium phosphate as described below: Procedure: • Add about 20 ml of anhydrous methanol to the titration vessel. • Titrate to the amperometric endpoint with karl fischer reagent. • Quickly add 0.2 g prednisolone sodium phosphate sample. • Stir for 1 minute and again titrate in the same way.
- 20. The karl Fischer method for the determinations of water is used for prednisolone sodium phosphate as described below: Procedure: • The endpoint is detected by electrode. • The minimum water equivalent is 3.5 mg of water per ml of karl fischer reagent.Hence the percentage of water in the given sample may be calculated by following equation: Water % (w/w) = 𝑣×3.5 𝑤𝑡.𝑜𝑓 𝑠𝑎𝑚𝑝𝑙𝑒 (𝑚𝑔) × 100
- 21. PH influence c c • PH between 5-7.5 is the optimum range • Below PH 2 reaction will not happen. • PH between 2-5 reaction will be slow. • Above PH 8 iodine is consumed by side reaction.
- 22. Application Increased Product Stability. E.g. pharma product or food product. Stopping growth of microorganisms by determining water level. Analytical technique for quantitative analysis of total water content.
- 23. High accuracy and precision. Selectivity for water. Short analysis duration. Easy sample preparation. Small sample quantities required. Nearly unlimited measuring range. Suitability for analyzing solids, liquids and gases.
- 24. Limitations High costs of Considerable amount of apparatus. Inference of compound reaction with iodine. Highly acidic or basic compound can not be determined. Large amount of sample needed in some cases. Water in carbonyl group is difficult to determine. Can show disadvantages with solid materials.