The Leclanché dry cell is used to run common devices such as ipads and cell phones....

Prepare a diagram of a galvanic cell that could be made from the reaction in Q10....

Prepare a diagram of a galvanic cell that could be made from the reaction in Q10. On your diagram, label the following: cathode, anode direction of electron flow direction of ion flow in the salt bridge write down the oxidation half reaction at the appropriate electrode write down the reduction half reaction at the appropriate electrode state the oxidizing agent and reducing agent g. Describe the cell using cell notation

A standard state galvanic cell is constructed from the half-cells described below. Half-Cell 1: Copper rod...

A standard state galvanic cell is constructed from the half-cells described below. Half-Cell 1: Copper rod in a solution containing 1.00 M Cu(NO3)2 Half-Cell 2: Silver rod in a solution containing 1.00 M AgNO3 a. Draw a diagram of the cell. Label the anode and cathode. Indicate the direction of electron flow across the wire and ion flow through the salt bridge. Write a balanced chemical equation for the cell reaction and calculate the E‹ and ΔG‹ for it. E‹:____________________________...

voltaic cell operation-For each of the cell shown below answer the following questions A. Sn |...

voltaic cell operation-For each of the cell shown below answer the following questions A. Sn | Sn 2+ (1M) || Pb 2+ (1M) |Pb B. Zn | Zn 2+ (1M) || Sn 2+ (1M) | Sn 1. identify anode and cathode 2. calculate the standard cell potential (is the cell reaction spontaneous?) 3. write the equation for the cell reaction which species is oxidized, reduced? Which species is the oxidizing agent and which one is the reducing agent? How many...

A voltaic cell is constructed with the given solutions of CuSO4 (0.130 M) and FeSO4 (0.0500...

A voltaic cell is constructed with the given solutions of CuSO4 (0.130 M) and FeSO4 (0.0500 M); 25.0 g strips of Cu and Fe; and a KNO3 salt bridge. Using a table displaying standard potentials (Eored) to answer the following commands.   (a) Write the equations for anode and the cathode half-reactions and the overall reaction. Write the line diagram (cell notation).   (b) Calculate Eo for the cell at 25 oC. (c) Calculate E for the cell at 25 oC.   (d)...

Electrochemical Cell Potentials Table 1: Electrochemical Cell Potentials Cell Measured Total Potential from Multimeter (V)1 Individual...

Electrochemical Cell Potentials Table 1: Electrochemical Cell Potentials Cell Measured Total Potential from Multimeter (V)1 Individual Half-Cell Potentials Cell Reactions5 ΔG (kJ)6 (Cu) Electrode Standard Potential (V)2 Metal Electrode Experimental Potential (V)3 Metal Electrode Theoretical Potential (V)4 Metal Electrode Potential % Error Cu | Sn 0.469 0.34 V 0.34-0.469 =-0.129 Cathode:       Cu2+ + 2e- -> Cu Anode:            Sn ->Sn2++ 2e- Net:          Cu2+ + Sn -> Cu + Sn2+ Cu | Al 0.796 0.34 V 0.34-0.796 =-0.456 Cathode:   Cu2+ +...

Consider the phenomena of Li intercalation of graphite at the anode of a Lithium Ion battery,...

Consider the phenomena of Li intercalation of graphite at the anode of a Lithium Ion battery, something you should have run across in your review. Intercalation of lithium metal in between the layers of graphite forms a thermodynamically stable compound whose formula is LiC6. At the cathode of a lithium ion battery is another bizarre chemical, typically lithium cobalt oxide (LiCoO2). The two half cell reactions can be expressed as follows: Li+1 + e- + C6 à LiC6                            Eo =...

1 a. The reaction between aluminum and iodine has this overall electrochemical cell: Al(s)| Al3+(aq)|| I2(aq),I-1(aq)|...

1 a. The reaction between aluminum and iodine has this overall electrochemical cell: Al(s)| Al3+(aq)|| I2(aq),I-1(aq)| Pt(s) Balance each of the two half-cell reactions and put them together to obtain the balanced overall reaction. Identify the oxidation and reduction half-cells, as well as the cathode and anode. b. Refer to the attached table of standard reduction potentials. Determine the standard potential (EO) for the overall reaction. Show all units. Is the reaction spontaneous? How can you tell? c. Write the...

The following reactions can be coupled to give alanine and oxaloacetate: RXN 1: glutamate + pyruvate...

The following reactions can be coupled to give alanine and oxaloacetate: RXN 1: glutamate + pyruvate --> ketoglutarate + alanine RXN 2 glutamate + oxaloacetate --> ketoglutarate + aspartate (a) Write the form of the equilibrium constant for the reaction: Pyruvate + aspartate --> alanine + oxaloacetate and calculate the numerical value of the equilibrium constant at 30 C. (b) In the cytoplasm of a certain cell, the components are at the following concentrations: [aspartate] = 1.00 x 10-2 M...

The following reactions can be coupled to give alanine and oxaloacetate: glutamate + pyruvate ↔ ketoglutarate...

The following reactions can be coupled to give alanine and oxaloacetate: glutamate + pyruvate ↔ ketoglutarate + alanine ∆Go ’rxn,303 = − 1004 J/mol glutamate + oxaloacetate ↔ ketoglutarate + aspartate ∆Go ’rxn,303 = − 4812 J/mol (a) Write the form of the equilibrium constant for pyruvate + aspartate ↔ alanine + oxaloacetate and calculate the numerical value of the equilibrium constant at 30o C. (b) In the cytoplasm of a certain cell, the components are at the following concentrations:...

1) The free energy change for the following reaction at 25 °C, when [Pb2+] = 1.18...

1) The free energy change for the following reaction at 25 °C, when [Pb2+] = 1.18 M and [Cd2+] = 7.90×10-3 M, is -65.9 kJ: Pb2+(1.18 M) + Cd(s)> Pb(s) + Cd2+(7.90×10-3 M) ΔG = -65.9 kJ What is the cell potential for the reaction as written under these conditions? Answer: ___V Would this reaction be spontaneous in the forward or the reverse direction? 2) Use the standard reduction potentials located in the 'Tables' linked above to calculate the standard...