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Accuracy of the Debye-Hückel limiting law Example: The mean activity coefficient in a 0.100 mol kg -1 MnCl 2 (aq) solution is 0.47 at 25 o C. What is the.

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Presentation on theme: "Accuracy of the Debye-Hückel limiting law Example: The mean activity coefficient in a 0.100 mol kg -1 MnCl 2 (aq) solution is 0.47 at 25 o C. What is the."— Presentation transcript:

1 Accuracy of the Debye-Hückel limiting law Example: The mean activity coefficient in a 0.100 mol kg -1 MnCl 2 (aq) solution is 0.47 at 25 o C. What is the percentage error in the value predicted by the Debye-Huckel limiting law? Solution: First use equation 10.4 to calculate the ionic strength and then use eq. 10.3 to calculate the mean activity coefficient. From eq. 10.4, I = ½(2 2 *0.1 + 1 2 *(2*0.1)) = 0.3 From eq. 10.3log(γ) = -|2*1|A*(0.3) 1/2 ; = - 2*0.509*0.5477 = - 0.5576 so γ = 0.277 Error = (0.47-0.277)/0.47 * 100% = 41%

2 Extended Debye-Hückel law (10.5) B is an adjustable empirical parameter.

3 Calculating parameter B Example : The mean activity coefficient of NaCl in a diluted aqueous solution at 25 o C is 0.907 (at 10.0mmol kg -1 ). Estimate the value of B in the extended Debye-Huckel law. Solution: First calculate the ionic strength I = ½(1 2 *0.01 + 1 2 *0.01) = 0.01 From equation 10.5 log(0.907) = - (0.509|1*1|*0.01 1/2 )/(1+ B*0.01 1/2 ) B = - 1.67

4 Half-reactions and electrodes Two types of electrochemical cells: 1. Galvanic cell: is an electrochemical cell which produces electricity as a result of the spontaneous reactions occurring inside it. 2. Electrolytic cell: is an electrochemical cell in which a non spontaneous reaction is driven by an external source of current.

5 Other important concepts include: Oxidation: the removal of electrons from a species. Reduction: the addition of electrons to a species. Redox reaction: a reaction in which there is a transfer of electrons from one species to another. Reducing agent: an electron donor in a redox reaction. Oxidizing agent: an electron acceptor in a redox reaction. Two type of electrodes: Anode: the electrode at which oxidation occurs. Cathode: the electrode at which reduction occurs

6 Typical Electrodes

7 Electrochemical cells Liquid junction potential: due to the difference in the concentrations of electrolytes. The right-hand side electrochemical cell is often expressed as follows: Zn(s)|ZnSO4(aq)||CuSO4(aq)|Cu(s) The cathode reaction (copper ions being reduced to copper metal) is shown on the right. The double bar (||) represents the salt bridge that separates the two beakers, and the anode reaction is shown on the left: zinc metal is oxidized into zinc ions

8 In the above cell, we can trace the movement of charge. –Electrons are produced at the anode as the zinc is oxidized –The electrons flow though a wire, which we can use for electrical energy –The electrons move to the cathode, where copper ions are reduced. –The right side beaker builds up negative charge. Cl- ions flow from the salt bridge into the zinc solution and K+ ions flow into the copper solution to keep charge balanced. To write the half reaction for the above cell, Right-hand electrode: Cu 2+ (aq) + 2e - → Cu(s) Left-hand electrode: Zn 2+ (aq) + 2e - → Zn(s) The overall cell reaction can be obtained by subtracting left-hand reaction from the right-hand reaction: Cu 2+ (aq) + Zn(s) → Cu(s) + Zn 2+ (aq)

9 Expressing a reaction in terms of half-reactions Example : Express the formation of H 2 O from H 2 and O 2 in acidic solution as the difference of two reduction half- reactions. Redox couple: the reduced and oxidized species in a half- reaction such as Cu 2+ /Cu, Zn 2+ /Zn…. Ox + v e - → Red The quotient is defined as: Q = a Red /a Ox Example: Write the half-reaction and the reaction quotient for a chlorine gas electrode.

10 Varieties of cells

11 Notation of an electrochemical cell Phase boundaries are denoted by a vertical bar. A double vertical line, ||, denotes the interface that the junction potential has been eliminated. Start from the anode.

12 Cell Potential Cell potential: the potential difference between two electrodes of a galvanic cell (measured in volts V). Maximum electrical work : w e,max = ΔG Electromotive force, E, Relationship between E and Δ r G: Δ r G = -νFE where ν is the number of electrons that are exchanged during the balanced redox reaction and F is the Faraday constant, F = eN A. At standard concentrations at 25 o C, this equation can be written as Δ r G θ = -νFE θ

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