Mr. Chapman Chemistry 30.  The table of Standard Reduction Potentials indicates which substances are the best at competing for electrons.  The higher.

Slides:

Advertisements

Similar presentations

Electrochemical & Voltaic Cells

Advertisements

Inorganic chemistry Assiastance Lecturer Amjad Ahmed Jumaa  Calculating the standard (emf) of an electrochemical cell.  Spontaneity.

Oxidation Reduction Reactions

Cells and Voltage.

Cells and Voltage.

Lecture 12: Cell Potentials Reading: Zumdahl 11.2 Outline –What is a cell potential? –SHE, the electrochemical zero. –Using standard reduction potentials.

STANDARD ELECTRODE POTENTIALS. THE STANDARD HYDROGEN ELECTRODE In order to measure the potential of an electrode, it is compared to a reference electrode.

Galvanic Cells What will happen if a piece of Zn metal is immersed in a CuSO 4 solution? A spontaneous redox reaction occurs: Zn (s) + Cu 2 + (aq) Zn 2.

Standard Electrode Potentials When the concentrations of Cu 2+ (aq) and Zn 2+ (aq) are both kept at unit activity, the emf of the galvanic cell is 1.10.

Electrochemistry II. Electrochemistry Cell Potential: Output of a Voltaic Cell Free Energy and Electrical Work.

VIII. Oxidation-Reduction J Deutsch An oxidation-reduction (redox) reaction involves the transfer of electrons (e - ). (3.2d) The oxidation numbers.

Electrochemical Cells (aka – Galvanic or Voltaic Cells) AP Chemistry Unit 10 Electrochemistry Chapter 17.

Standard Cell Notation (line notation)

ELECTROCHEMISTRY Chap 20.

Electron-Transfer Reactions Cu 2+ (aq) + Zn(s)  Cu(s) + Zn 2+ (aq)

Lecture 11: Cell Potentials Reading: Zumdahl 11.2 Outline –What is a cell potential? –SHE, the electrochemical zero. –Using standard reduction potentials.

Electron-Transfer Reactions Cu 2+ (aq) + Zn(s)  Cu(s) + Zn 2+ (aq)

1 ELECTROCHEMICAL CELLS Chapter 20 : D8 C Half-Cells and Cell Potentials > 2 Copyright © Pearson Education, Inc., or its affiliates. All Rights.

Electrochemistry Chapter and 4.8 Chapter and 19.8.

Lecture 244/1/05. Quiz 1) Balance the following redox equation: Ag(s) + NO 3 -  NO 2 (g) + Ag + (aq) 2) What is the oxidation number for Chlorine in.

Redox.  Redox involves two simultaneous reactions ◦ An oxidation and a reduction  Oxidation involves a loss of electrons  Reduction involves a gain.

Reduction Potential and Cells

Putting redox reactions to work.  Electrons are transferred  Lose Electrons Oxidation  Gain Electrons Reduction.

Chapter 21: Electrochemistry II

1 Chapter Eighteen Electrochemistry. 2 Electrochemical reactions are oxidation-reduction reactions. The two parts of the reaction are physically separated.

Spontaneous Redox Reactions

Chapter 21 Electrochemistry 21.2 Half-Cells and Cell Potentials

Chapter 20 Electrochemistry and Oxidation-Reduction.

Unit 14: ElectrochemLPChem: Wz. Unit 14: Electrochemistry.

17-Nov-97Electrochemistry (Ch. 21)1 ELECTROCHEMISTRY Chapter 21 Electric automobile redox reactions electrochemical cells electrode processes construction.

Warmup 2. Balance this redox reaction in acid: + Fe 2+ + Cr 2 O 7 2-  Fe 3+ + Cr 3+ Ni e¯  Ni E° = V Zn e¯  Zn E° = V 1. Write.

Standard Voltages Reading: Masterson 18.2 Outline –What is a standard voltage (cell potential) –SHE, the electrochemical zero. –Using standard reduction.

Mr. Chapman Chemistry 30 ELECTROCHEMICAL CELLS AND REDOX REACTIONS.

Electrochemical cell. Parts of a Voltaic Cell The electrochemical cell is actually composed to two half cells. Each half cell consists of one conducting.

Electrochemistry - Section 1 Voltaic Cells

Galvanic Cell: Electrochemical cell in which chemical reactions are used to create spontaneous current (electron) flow.

Voltaic Cells/Galvanic Cells and Batteries. Background Information Electricity is the movement of electrons, and batteries are an important source of.

Chapter 18 Notes1 3. standard reduction potentials by convention, half-reactions are written as reductions; to get the overall reaction, use right electrode.

III.Electrochemical Cells (continued): Calculating Cell Voltages  The standard voltage for any electrochemical cell can be calculated from the theoretical.

Batteries Electrochemical cells  Terms to know Anode Cathode Oxidation Reduction Salt Bridge Half cell Cell potential Electron flow Voltage.

Cell EMF Eocell = Eored(cathode) - Eored(anode)

Chapter 20: Electrochemistry Chemistry 1062: Principles of Chemistry II Andy Aspaas, Instructor.

Reduction- Oxidation Reactions (1) 213 PHC 9 th lecture Dr. mona alshehri (1) Gary D. Christian, Analytical Chemistry, 6 th edition. 1.

Galvanic Cells ELECTROCHEMISTRY/CHEMICAL REACTIONS SCH4C/SCH3U.

Unit 2: Electrochemistry Electrolysis

Chapter 19 Last Unit Electrochemistry: Voltaic Cells and Reduction Potentials.

Electrochemistry An electrochemical cell produces electricity using a chemical reaction. It consists of two half-cells connected via an external wire with.

ELECTROCHEMICAL CELLS. ELECTROCHEMISTRY The reason Redox reactions are so important is because they involve an exchange of electrons If we can find a.

10.3 Half-reactions and electrodes

1 © 2006 Brooks/Cole - Thomson OXIDATION-REDUCTION REACTIONS Indirect Redox Reaction A battery functions by transferring electrons through an external.

18.4 Standard Electrode Potentials Maggie Hanson.

CE Chemistry Module 8. A. Involves electron changes (can tell by change in charge) Cl NaBr 2NaCl + Br 2 B. Oxidation 1. First used.

The Daniell cell was invented by John Daniell in 1836.

Electrochemistry. #13 Electrochemistry and the Nernst Equation Goals: To determine reduction potentials of metals To measure the effect of concentration.

In voltaic cells, oxidation takes place at the anode, yielding electrons that flow to the cathode, where reduction occurs. Section 1: Voltaic Cells K What.

Electrochemistry. Terminology You may have noticed oxygen never gets oxidized, it always gets reduced. The reason for this is because oxygen is an oxidizing.

Electrochemistry Lesson 2

Chapter 20 Electrochemistry

Chapter 10.7 Electrolysis.

Wednesday, January 13th Grab a AP exam registration form from next to the projector if you don’t already have one Take out review questions 1-8 and your.

Cell Potential and the Nernst Equation

Unit 7: Redox Cell Potentials.

THE VOLTAIC (GALVANIC) ELECTROCHEMICAL CELL. 4/26

Electrochemical Cells (Batteries)

AP Chem Get HW checked Work on oxidation # review

AP Chem Get HW checked Take out laptops and go to bit.ly/GalCell

Electrochemistry.

Standard Electrode Potentials

Presentation transcript:

Mr. Chapman Chemistry 30

 The table of Standard Reduction Potentials indicates which substances are the best at competing for electrons.  The higher the value for E°, the better that half-reaction is at competing for electrons.  In an electrochemical cell, the half-reaction with the highest value of E° will be reduced, and hence will be the cathode in the cell.

 Which of the following will be reduced if an electrochemical cell is made between the two reactions? E° Cu 2+ (aq) + 2e - → Cu (s) 0.34 V Zn 2+ (aq) + 2e - → Zn (s) V Answer: Copper will be reduced. This is because copper is better at competing for electrons, so it will force zinc to be oxidized. Notice that above we wrote both of the reactions as reductions.

 When we create an electrochemical cell, we have a special notation that we use to show the formation of the cell.  For example, to write down in short form the cell formed between the Zn and Cu half-cells in the previous examples, we write this: Cu|Cu 2+ || Zn|Zn 2+

 Since we now know whether it is copper or zinc being oxidized (zinc is being oxidized), we can calculate the voltage for the cell by reversing the zinc half-reaction. E° Cu 2+ (aq) + 2e - → Cu (s) 0.34 V Zn (s) → Zn 2+ (aq) + 2e V Cu 2+ (aq) + Zn (s) → Zn 2+ (aq) + Cu (s) = 1.10 V

1. Write down both of the half-reactions involved in the electrochemical cells. 2. Use the standard potential reduction table to determine the voltage of each half-reaction. 3. Determine which half-reaction will undergo oxidation and which will undergo reduction. 4. Switch the direction of the equation that undergoes oxidation, as well as the sign of the voltage. Add the voltages together.

 The voltage of an electrochemical cell will always be positive. Reactions with a positive E° are always spontaneous, and all electrochemical cells are spontaneous reactions.  This makes it easy to see which equation to flip before you add them together. Just flip the equation that will give you a positive voltage.  Important: Before you add voltages, you need to balance the equation. This does not, however, changes values for E°.

 Using your Standard Reduction Potential Table, determine the voltage of the following circuits: 1. Al|Al 3+ and Pb|Pb Na|Na + and Mg|Mg Cu|Cu 2+ and Cd|Cd 2+