Voltaic Cells

1. Voltaic Cells

2. The Nature of Electrochemical Cells • When iron metal is dipped into an aqueous solution of blue copper sulfate, the iron becomes copper plated • Why? • The iron loses e- to the copper • What type of reaction is this???? Fe(s) + Cu2+(aq) Fe2+(aq) + Cu (s)

3. Fe FeSO4(aq) CuSO4(aq) Zn Copper Plating – An Example Fe Cu Since the copper is plating the iron, the solution will get lighter as more copper is used.

4. Does the reverse happen? Fe(s) + Cu2+(aq) Fe3+(aq) + Cu (s) Can we go backwards?…. Fe(s) + Cu2+(aq) Fe3+(aq) + Cu (s) • Some metals are better reducing agents than others • (AKA: some metals lose e- easier than others.) • The reaction is only spontaneous one way… the reverse reaction requires an outside source of energy to work.

5. The Nature of Electrochemical Cells • Electrochemical process: conversion between chemical and electrical energy • All involve redox reactions • To capture the electrical energy, the two half-reactions must be physically separated • Called electrochemical cells • Can create electricity or be used to create a chemical change

6. Voltaic Cells • Invented by Alessandro Volta in 1800 • Voltaic cells: electrochemical cells used to convert chemical energy into electrical energy • Examples  flashlights or battery-powered calculators • Made of half cells • One part of the voltaic cell where oxidation or reduction is occurring

7. Schematic for separating the oxidizing and reducing agents in a redox reaction. 8H+ + MnO4- + 5e- Mn2+ + 4H20 ; Fe2+  Fe3+ + e-

8. Why won’t the reaction continue?? Build up of charges would require large amounts of energy Solutions must be connected to allow ions to flow! 8H+ + MnO4- + 5e- Mn2+ + 4H20 ; Fe2+  Fe3+ + e-

9. Salt Bridge: contains a strong electrolyte held in place by gel Porous Disk: allows ion flow without mixing solutions Allows ions to pass between solutions, but doesn’t allow the solutions to mix

10. Parts of a Voltaic Cell • Electrode: • Conductor in a circuit that carries electrons to a metal • Anode = oxidation • Negatively charged • Cathode = reduction • Positively charged

11. Steps of a Voltaic Cell • e- created at anode • Shown in oxidation half-reaction • e- leave zinc and pass through wire • e- enter cathode and cause reduction • Shown in half-reaction • Positive and negative ions pass through salt bridge to finish the circut

12. Oxidation half-reaction Zn(s) Zn2+(aq) + 2e- Reduction half-reaction Cu2+(aq) + 2e- Cu(s) Overall (cell) reaction Zn(s) + Cu2+(aq) Zn2+(aq) + Cu(s) A voltaic cell based on the zinc-copper reaction. Figure 21.5

13. Schematic of a battery. Electron flow anode to cathode (- to +) oxidation to reduction reducing agent to oxidizing agent

14. Cu/Zn Voltaic Cell • Cu2+ + 2e-  Cu Cathode/reduction • Zn  Zn2+ + 2e- Anode/oxidation • Cu2+ + Zn  Zn2+ + Cu Cu Zn SO42- Zn2+ Cu2+ Zn2+

15. Voltaic Cell Shorthand • Oxidation half cell is listed first with reduced and oxidized species separated by a line. • Reduction is next in the opposite order. • Double line separates the two and represents a salt bridge. Zn|Zn2+||Cu2+|Cu

16. Voltaic Cell Shorthand • Draw shorthand notation for a Mg-Pb cell where the nitrate ion is present. You might want to refer to the activity series to determine what is oxidized and what is reduced! • Draw a diagram for this voltaic cell on the back or bottom of your notes! • Label: anode, cathode, direction of e- flow • Write-out the ½ rxns and combined reaction.