AP+Chem+Lab+13

In electrochemistry, a voltaic cell is a specially prepared system in which an oxidation-reduction reaction occurs spontaneously. This spontaneous reaction produces an easily measured electrical potential. Voltaic cells have a variety of uses. In this experiment, you will prepare a variety of semi-microscale voltaic cells in a 24-well test plate. A voltaic cell is constructed by using two metal electrodes and solutions of their respective salts (the electrolyte component of the cell) with known molar concentrations. In Parts I and II of this experiment, you will use a Voltage Probe to measure the potential of a voltaic cell with copper and lead electrodes. You will then test two voltaic cells that have unknown metal electrodes and, through careful measurements of the cell potentials, identify the unknown metals. In Part III of the experiment, you will measure the potential of a special type of voltaic cell called a concentration cell. In the first concentration cell, you will observe how a voltaic cell can maintain a spontaneous redox reaction with identical copper metal electrodes, but different electrolyte concentrations. You will then measure the potential of a second concentration cell and use the Nernst equation to calculate the solubility product constant, //Ksp//, for lead iodide, PbI2. In this experiment, you will
 * Introduction **
 * Objectives **
 * Prepare a Cu-Pb voltaic cell and measure its potential.
 * Test two voltaic cells that use unknown metal electrodes and identify the metals.
 * Prepare a copper concentration cell and measure its potential.
 * Prepare a lead concentration cell and measure its potential.
 * Use the Nernst equation to calculate the //Ksp// of PbI2.


 * Materials **
 * Vernier computer interface
 * computer Voltage Probe
 * three 10 mL graduated cylinders
 * 24-well test plate
 * string
 * Cu and Pb electrodes
 * two unknown electrodes, labeled X and Y
 * 150 mL beaker
 * 0.10 M copper (II) nitrate, Cu(NO3)2, solution
 * 0.10 M lead (II) nitrate, Pb(NO3)2, solution
 * 1.0 M copper (II) sulfate, CuSO4, solution
 * 0.050 M potassium iodide, KI, solution
 * 1 M potassium nitrate, KNO3, solution
 * 0.10 M X nitrate solution
 * 0.10 M Y nitrate solution
 * steel wool
 * plastic Beral pipets

Use the table of standard reduction potentials in your text, or another approved reference, to complete the following table. An example is provided. Cu || Zn(s) à Zn2+ + 2e- Cu2+ + 2e- à Cu(s) || +0.76 V +0.34V || +1.10V || Pb ||  ||   ||   || Ag ||  ||   ||   || Mg ||  ||   ||   || Zn ||  ||   ||   ||
 * Prelab **
 * Electrodes || Half-reactions || Eo (each rxn) || Eo cell ||
 * Zn
 * Cu
 * Pb
 * Pb
 * Pb

__ Part I Determine the E ____ o ____ for a Cu-Pb Voltaic Cell __
 * Procedure **
 * 1) Obtain and wear goggles.
 * 2) Use a 24-well test plate as your voltaic cell. Use Beral pipets to transfer small amounts of 0.10 M Cu(NO3)2and 0.10 M Pb(NO3)2solution to two neighboring wells in the test plate. ** CAUTION: **// Handle these solutions with care. If a spill occurs, ask your instructor how to clean up safely. //
 * 3) Obtain one Cu and one Pb metal strip to act as electrodes. Polish each strip with steel wool. Place the Cu strip in the well of Cu(NO3)2solution and place the Pb strip in the well of Pb(NO3)2 solution. These are the half cells of your Cu-Pb voltaic cell.
 * 4) Make a salt bridge by soaking a short length of string in a beaker than contains a small amount of 1 M KNO3 solution. Connect the Cu and Pb half cells with the string.
 * 5) Connect a Voltage Probe to Channel 1 of the Vernier computer interface. Connect the interface to the computer with the proper cable.
 * 6) Start the Logger // Pro // program on your computer. Open the file “20 Electrochemistry” from the // Advanced Chemistry with Vernier // folder.
 * 7) Measure the potential of the Cu-Pb voltaic cell. Complete the steps quickly to get the best data.
 * 8) Click START to start data collection.
 * 9) Connect the leads from the Voltage Probe to the Cu and Pb electrodes to get a positive potential reading. Click KEEP immediately after making the connection with the Voltage Probe.
 * 10) Remove both electrodes from the solutions. Clean and polish each electrode.
 * 11) Put the Cu and Pb electrodes back in place to set up the voltaic cell. Connect the Voltage Probe to the electrodes, as before. Click KEEP immediately after making the connection with the Voltage Probe.
 * 12) Remove the electrodes. Clean and polish each electrode again.
 * 13) Set up the voltaic cell a third time. Click KEEP immediately after making the connection with the Voltage Probe. Click STOP to end the data collection.
 * 14) Click the Statistics button, or use from pull down menu. Record the mean in your data table as the average potential. Close the statistics box on the graph screen by clicking the X in the corner of the box.

__ Part II: Determine the E ____ o ____ for Two Voltaic Cells Using Pb and Unknown Metals __
 * 1) Obtain a small amount of the unknown electrolyte solution labeled “0.10 M X” and the corresponding metal strip, X.
 * 2) Use a Beral pipet to transfer a small amount of 0.10 M X solution to a well adjacent to the 0.10 M Pb(NO3)2solution in the test plate.
 * 3) Make a new salt bridge by soaking a short length of string in the beaker of 1 M KNO3solution. Connect the X and Pb half cells with the string.
 * 4) Measure the potential of the X-Pb voltaic cell. Complete this step quickly.
 * 5) Click START to start data collection.
 * 6) Connect the leads from the Voltage Probe to the X and Pb electrodes to get a positive potential reading. Click KEEP immediately after making the connection with the Voltage Probe.
 * 7) Remove both electrodes from the solutions. Clean and polish each electrode.
 * 8) Set up the voltaic cell again. Connect the Voltage Probe as before. Click KEEP immediately after making the connection with the Voltage Probe.
 * 9) Remove the electrodes. Clean and polish each electrode again.
 * 10) Test the voltaic cell a third time. Click KEEP immediately after making the connection with the Voltage Probe.
 * 11) Click STOP to end data collection.
 * 12) Click the Statistics button, or use from pull down menu. Record the mean in your data table as the average potential and then close the statistics box on the graph screen by clicking the X in the corner of the box.
 * 13) Repeat Steps Part 2 Procudure using the unknown and its corresponding electrolyte solution labeled “Y”.

__ Part III Prepare and Test Two Concentration Cells __
 * 1) Set up and test a copper concentration cell.
 * 2) Prepare 20 mL of 0.050 M CuSO4solution by mixing 1 mL of 1.0 M CuSO4solution with 19 mL of distilled water.
 * 3) Set up a concentration cell in two wells of the 24-well test plate by adding 5 mL of 0.050 M CuSO4solution to one well and 5 mL of 1.0 M CuSO4solution to a neighboring well. Use Cu metal electrodes in each well. Use a KNO3-soaked string as the salt bridge, as in Parts I and II.
 * 4) Click START to start data collection.
 * 5) Test and record the potential of the concentration cell in the same manner that you tested the voltaic cells in Parts I and II.
 * 6) Set up a concentration cell to determine the solubility product constant, // K //// sp //, of PbI2.
 * 7) Prepare 10 mL of 0.050 M Pb(NO3)2solution by mixing 5 mL of 0.10 M Pb(NO3)2 solution with 5 mL of distilled water.
 * 8) Mix 9 mL of 0.050 M KI solution with 3 mL of 0.050 M Pb(NO3)2solution in a small beaker. In this reaction, most of the Pb2+ and I– will form the precipitate PbI2, but a small amount of the ions will remain dissolved.
 * 9) Set up the half cells in neighboring wells of the 24-well test plate. Place 5 mL of 0.050 M Pb(NO3)2 solution in one half cell, and 5 mL of the PbI2 mixture, from the small beaker, into an adjacent half cell. Use Pb electrodes in each half cell. Use a KNO3-soaked string as the salt bridge.
 * 10) Test and record the potential of the cell in the same manner that you tested the voltaic cells and the copper concentration cell.
 * 11) Discard the electrodes and the electrolyte solutions as directed. Rinse and clean the 24-well plate. ** CAUTION: **// Handle these solutions with care. If a spill occurs, ask your instructor how to clean up safely. //


 * Data Tables **
 * Results of Parts I and II || Cu/Pb || X/Pb || Y/Pb ||
 * Average cell potential (V) ||  ||   ||   ||


 * Results of Parts I and II || Cu/Pb || X/Pb || Y/Pb ||
 * Average cell potential (V) ||  ||   ||   ||


 * Post Lab**
 * 1) (Part I) Compare the average cell potential, for your Cu/Pb cell, with the E°cell that you calculated in the pre-lab exercise. Explain why your cell potential is different from the text value.


 * 1) (Part II) The unknown metals X and Y were either magnesium, silver, or zinc. Use the text value for the reduction potential of Pb and the measured cell potentials for the unknowns to identify X and Y.


 * 1) (Part III) Use the Nernst equation to calculate the theoretical value of // E // of the copper- concentration cell and compare this value with the cell potential that you measured.


 * 1) (Part III) Use the Nernst equation and the information that you collected about the Pb/PbI2 cell to complete the following calculations.
 * 2) Use the cell potential for the Pb-PbI2 cell and the known [Pb2+] to calculate the [Pb2+] in equilibrium with PbI2.
 * 3) Use the original diluted [Pb2+] and [I -] to calculate the [I-] in solution.
 * 4) Use your data to calculate the // K //// sp // of PbI2
 * 5) The accepted value of the // K //// sp // of PbI2is 9.8 × 10–9. How does your experimental // K //// sp // of PbI2compare with the accepted value?