![pH
We found that s= 0.011 molL-1, [Ca2+] =0.011 molL-1 ,
Hence, [OH-] = 2x0.011 molL-1 = 0.022 molL-1
pOH= -log[OH-]= 1.66
pH= 14-pOH=14-1.66= 12.34 for both solutions](https://image.slidesharecdn.com/lecture23-220822133419-73a6802c/85/Lecture2-3-pdf-36-320.jpg)
Lecture2&3.pdf
- 1. 뇨 뇨 뇨 뇨al 뇨i ㈠〱 0 i 60 a0nl ꤐͶͶ꾨 ꤐ 꾨 꾨 ‵ꤐ ‵ꤐ 꾨 꾨 6 꾨 ‵ꤐ ꤐ ꤐ6 6꾨 꾨 ꤐl꾨 ‵ꤐ ꤐ ꤐ 꾨 “ 6ꤐ ! 6ꤐ 1‵ 꾨l, 6ꤐ ꤐ〴 〴 꾨l, 6ꤐ 〴꾨 Ͷꤐ 〴6 ꤐ 꾨l, ꤐ 6ꤐ ꤐ Ͷ ꤐ Ͷ 6ꤐ 〴l 〴l ꤐ‵ l꾨 꾨l 6ꤐ 꾨Ͷꤐ 꾨〴l ” ( ꤐ- Ͷꤐ ꤐ, ‵ꤐ - 1- 1)
- 2. What is electrochemistry? Electrochemistry is the part of chemical sciences that deals with heterogeneous electron transfer reactions. Applications 1) Sensor : Glucose senor, pH sensor, arsenic sensor etc 2) Energy: (a) Battery: Dry cell, lead storage cell etc (b) Fuel cell: Methanol fuel cell 3) Electroplating 4) Wastewater treatment etc
- 3. In chemistry and manufacturing, electrolysis is a technique that uses a direct electric current (DC) to drive an otherwise non-spontaneous chemical reaction. Faraday's law of electrolysis : The amount of substance produced at each electrode is directly proportional to the quantity of charge flowing through the cell. Electrolysis
- 4. Problem 1: Find the charge in coulomb on 1 mole-ion of N3-. Solution: Charge on one ion of N3- = 3 × 1.6 × 10-19 coulomb Thus, charge on one mole-ion of N3- = 3 × 1.6 10-19 × 6.02 × 1023 = 2.89 × 105 coulomb Problem 2 How much charge is required to reduce (a) 1 mole of Al3+ to Al and (b)1 mole of KMnO4 to Mn2+ ? Solution: ( a ) T h e r e d u c t i o n r e a c t i o n i s Al3+ + 3e- → Al Thus, 3 mole of electrons are needed to reduce 1 mole of Al3+ Q = 3 × F = 3 × 96500 = 289500 coulomb (b) The reduction is M n 4 - + 8 H + 5 e - → M n 2 + + 4 H 2 O 1 m o l e 5 m o l e Q = 5 × F = 5 × 96500 = 48500 coulomb Electrolysis
- 5. Problem3. How much electric charge is required to oxidise (a) 1 mole of H2O to O2 and (b)1 mole of FeO to Fe2O3? Solution: (a) The oxidation reaction is H 2 O → 1 / 2 O 2 + 2 H + + 2 e - Q = 2 × F = 2 × 96500 =193000 coulomb (b) The oxidation reaction is F e O + 1 / 2 H 2 O → 1 / 2 F e 2 O 3 + H + + e - Q = F = 96500 coulomb Problem 4. Exactly 0.4 faraday electric charge is passed through three electrolytic cells in series, first containing AgNO3, second CuSO4 and third FeCl3 solution. How many gram of rach metal will be deposited assuming only cathodic reaction in each cell? Solution: The cathodic reactions in the cells are respectively. Ag+ + e- → Ag Cu2+ + 2e- → Cu and Fe3+ + 3e- → Fe Hence, Ag deposited = 108 × 0.4 = 43.2 g Cu deposited = 63.5/2×0.4=12.7 g and Fe deposited = 56/3 ×0.4=7.47 g Electrolysis FeCl3 1F can react with 1 mole charge
- 6. Problem5. An electric current of 100 ampere is passed through a molten liquid of sodium chloride for 5 hours. Calculate the volume of chlorine gas liberated at the electrode at NTP. Solution: The reaction taking place at anode is Cl- → 1/2Cl2 + e- Q = I × t = 100 × 5 × 3600 = 180,0000 coulomb = 18.65 F 1F can liberate 0.5 mol Cl2 gas Hence, 18.65F can liberate 9.32 mol Cl2 gas Now PV= nRT, or V = nRT/P = 9.32 mol x 22.4 L (at NTP) = 208.91 L Electrolysis
- 8. I = nuAq
- 11. Solvation of ions having same charge
- 12. • Small ions may have larger electric field. • An ion with stronger electric field carries more solvent (water) molecules with it when it moves through the solution. • Small ions may have bigger Stokes radius. a: hydrodynamic radius (Stokes radius) fs fric F -----2r------ Ffric Hydration sphere r f 6
- 13. The mobilities of ions + - - - - - - - - - - - - - - - - + + + + + + + + + + + + + + + Electric field E + - s Mobility: Drift speed s : f ze s E E u s r ze f ze u 6 + -----2a------ S Ffric=fs Felec=zeE
- 14. Relative ionic size and mobility For different ions with the same charge such as Li+, Na+ and K+ the electrical forces are equal, so that the drift speed and the mobility are inversely proportional to the radius. In fact, conductivity measurements show that ionic mobility increases from Li+ to Cs+. Ionic mobility solvation
- 15. Questions 1) Define drift velocity and Ionic mobility. 2) Show how ionic mobility of a ion is related to physical parameters such as viscosity of medium, charge of ion and size of the ion. 3) Although K+ is larger than Li+ but ionic mobility of K+ is higher. Explain. 4) At infinite dilution, calculate molar conductance of ions of group-1 elements. 5) What is the order of ionic mobility of ions of alkaline metals? 6) Why KCl and KNO3 are used as supporting electrolytes or used in salt bridge? 7) Why KCl is better than NaCl in reducing blood pressure?
- 16. Questions 8) Define hydrodynamic radius and ionic radius. 9) The Cs+ cations with z=1 and hydrodynamic radius (taken as the ion radius plus the first hydration sphere) r=170 pm move in a solution with viscosity of 1.0 cP (1.0╳ 10-3kg m-1s-1). Estimate the mobility of the cation. Mah-che@sust.edu mahtazim@yahoo.com
- 17. End of lecture 2 May Allah SWT be with you and keep you safe from all evil effects and diseases Stay fine Allahhafez
- 18. Lecture 3 What different ways ions and molecules use to move in solution? Ions 1) Convection 2) Migration 3) Diffusion Molecules 1) Convection 2) Diffusion
- 21. Steps of electrochemical process (1) mass transfer (2) adsorption- (4) desorption (3) Electron transfer (5) mass transfer
- 22. • When we perform electrochemical experiments, we stop covection by keeping the system ( electrochemical cell) rest such that no external force can cause any movement of ions. • Diffusion of ions are natural as near the electrode surface mass vacancy is created when electrolysis is performed. Hence, often ionic mobility near the electrode surface is strongly dependent on difussion of ions/molecules.
- 23. 1) If electrode is highly active then near the electrode difusssion is dominent near the electrode surface Diffision Diffision (bulk) 2) If electrode is less active then in all cases ion moves due to migration only. Important
- 24. Diffusion For an efficient electrolysis process, near the electrode surface concentration of ions is decreased, so ionic mobility is highly dependent on diffision of ions. Diffision layer ET ET rate mass transfer rate
- 26. Molar conductivity Around the diffusion layer J = sc where s= dirift velocity and c = concentration Hence, J = sc = RT DF dx dc c D s or dx dc D sc or sc dx dc D J 1 , , Fick's first law of diffusion
- 27. We know that uE s Ionic mobility is proportional to ionic charge , hence zs uE E zs u zD zsl l zs u / where, D= sl, l is the distance between two electrodes and is the potential between two electrodes Note that potential = RT/F, thus the above expression can be written as RT zFD u Relation between Molar conductivity and diffusion s= drift velocity ( cm s-1) u= ionic mobility (cm2 V-1s-1 E= potential applied per unit distance (Vcm-1) = applied potential (V) l= distance between electrodes (cm) D=diffusion coefficient (cm2s-1) z= charge number
- 28. Now we know that = zuF and Combining these two equations , we get RT F D z v D z v 2 2 2 ) ( RT zFD u This equation is known as Einstein- Nernst equation and explains that (i) Molar conductivity is proportional to diffision coefficient (ii) Molar conductivity is a function of square of charge on the ion This equation can be written to represent molar conductivity of an electrolyte as RT DF z 2 2 Important: This equation represents molar conductivity assuming that electrolytes are fully dissociated. For weak or sparigly soluble salts, molar conductivity is valid at infinite dilution.
- 29. Molar conductivity: is the conductivity of one mole ion or electrolyte at infinite dilution. Hence, one can compare conductivity at infinite dilution only. It is only applicable at infinite dilution to compare two or more ionic species. But at a given concentration, the specific conductivity can best explain the relative strength of conductivity. Specific conductivity is the conductivity of ions/eelctrolytes in present in 1cm3 volume of solution Units: Molar conductivity- Scm2 mol-1 Specific conducttivity- Scm-1
- 30. Consequently, specific conductivity largely dependent on concentration of electrolyte/ions and charge. How specific conductivity is related to ionic mobility and concentration? We know that = zuF (1) (2) where is specific conductance and C is concentration Combining these two equations we get or, (3) so, k depends on charge of ions, ionic mobility and concentration
- 31. Both salts are sparingly soluble in water and even under saturated condition they are only slightly dissociated. So molar conductivity calculation will not give perfect result. Hence, we have to calculate specific conductivity. in case of satuarated Ba(NO3)2 ksp = 4.64x10-3 Thus, s = 0.1 molL-1 = 1.0x10-4 mol cm-3, i.e CBa2+ = 1.0x10-4 mol cm-3 CNO3-= = 2.0x10-4 mol cm-3 u (Ba2+) = 6.6x10=4 cm2V-1s-1 and u (NO3-) = 7.41x10-4 cm2V-1s-1. Now, using the following equation specific conductivity of barium and nitrate ions could be calculated separately k(Ba2+) = 1.27x10-5 Scm-1 and k(NO3-) = 1.43x10-5 Scm-1 and solution conductivity is (1.27+1.43)x10-5 Scm-1 =2.70x10-5 Scm-1
- 32. Comparison of saturated Ba(NO3)2 and BaSO4 solutions Similarly, in case of satuarated BaSO4 ksp = 1.08x10-10 Thus, s = 1.04x10-5 molL-1 = 1.04x10-8 mol cm-3, i.e CBa2+ = 1.04x10-8 mol cm-3 CSO4= = 1.04x10-8 mol cm-3 u (Ba2+) = 6.6x10-4 cm2V-1s-1 and u (SO4) = 8.29x10-4 cm2V-1s-1. Now, using the following equation specific conductivity of barium and sulphate ions could be calculated separately k(Ba2+) = 1.32x10-9 Scm-1 and k(SO4) = 1.67x10-9 Scm-1 and solution conductivity is (1.32+1.67)x10-9 Scm-1 =2.98x10-9 Scm-1 This means that kBa(NO3)2/kBaSO4 10,000
- 33. In two beakers A and B (containing 100ml water each), 0.74g and 1.48g Ca(OH)2 was added. Which one was more conductive? What was their pH values? Add of salt to a fixed volume of solvent/ g Ca(OH)2 (s) Ca2+(aq) + 2OH- (aq) concentration solubility, s saturation point saturated solution u n s a t u r a t e d Ca(OH)2 is a sparingly soluble base
- 34. Ca(OH)2 Add of salt to a fixed volume of solvent/ g Ca(OH)2 (s) Ca2+(aq) + 2OH- (aq) concentration solubility, 0.011 M saturation point, 0.0814 g/100 ml saturated solution u n s a t u r a t e d solubility, 0.011 M = 0.814 g/L Ca(OH)2 or, 0.0814 g /100 ml Ca(OH)2 makes the solution satuartaed. But we added 0.74 and 1.48 g salt.........! A ksp = 5.02x10-6 solubility, s= 0.011 molL-1
- 35. So maximum concentration of dissolved Ca(OH)2 both in A and B beakers were same and it was 0.011 mol/L = 1.1x10-5 mol cm-3 . Hence, their conductivity and pH were also same. CCa2+= 1.1x10-5 mol cm-3 , and COH-= 2.2x10-5 mol cm-3 , uCa2+= 6.17x10-4 cm2V-1s-1, uOH- = 20.64x10-4 cm2V-1s-1, uCa2+= 2, uOH-=1 Now applying kCa2+ =1.31x10-6 Scm-1, and kOH- =4.38x10-6 Scm-1 Total conductivity k= kOH-+kCa2+ = 5.70x10-6 Scm-1
- 36. pH We found that s= 0.011 molL-1, [Ca2+] =0.011 molL-1 , Hence, [OH-] = 2x0.011 molL-1 = 0.022 molL-1 pOH= -log[OH-]= 1.66 pH= 14-pOH=14-1.66= 12.34 for both solutions
- 38. Questions: 1) Write down the modes of mass transfer. Define each terms. 2) Draw an electrochemical system illustrating bulk and diffusion layer. 3) Under what condition diffusion coefficient can be used inplace of ionic mobility to determine molar conductivity? 4) Write the basis of Fick's first law of diffusion. 5)Deduce Einstein-Nernst equation. 6) Define weak electrolyte and sparingly soluble salt. 7) Between 'molar conductivity' and 'specific conductivity', which one will you select to know the relative conductivity of a solution? Explain. 8) Calculate molar conductivity of NaCl, Na2SO4, Ca(NO3)2 using diffusion coeifficient and specific conductivity of 0.05 M solutions using ionic mobility. Repeat the calculation for barium salts. 9) Write down the different steps of an electrochemical process ocuuring at an electrode surface. 10) When we a reaction to be diffusion controlled?
- 39. End of lecture 3