Fuel cells Learning objectives: Revise the work covered so far on module 2 of EEE. Explain that a fuel cell uses the energy from the reaction of a fuel.

Slides:

Advertisements

Similar presentations

A Determine the oxidation number for each atom in the following molecules H2S P2O5 S8 SCl2 Na2SO3 6. SO NaH Cr2O7-2 SnBr4 10. Ba(OH)2 For practice.

Advertisements

Electricity from Chemical Reactions

Ch. 21 Honors Chem. Electrochemistry

Chapter 20: Electrochemsitry A.P. Chemsitry Oxidation-Reduction Reactions Oxidation-reduction reactions (or redox reactions) involve the transfer.

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

Cells and Voltage.

Cells and Voltage.

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.

Redox Equilibria. Redox equilibria When a metal electrode is placed into a solution of one of its salts two things can happen; 1) Metal ions go into solution;

Electrochemical Cells. Definitions Voltaic cell (battery): An electrochemical cell or group of cells in which a product-favored redox reaction is used.

ELECTROCHEMICAL CELLS

Voltaic Cells Harnessing the power of Redox Redox Basics Redox Reactions happen when –one substance loses electrons (oxidized) and –one gains electrons.

Chapter 18 Electrochemistry. Redox Reaction Elements change oxidation number  e.g., single displacement, and combustion, some synthesis and decomposition.

Lecture 233/12/06. What is a REDOX reaction? OXIDATION: Ca(s)  Ca 2+ REDUCTION: 2H +  H 2 (g) OIL RIG Combined (net): REDOX REACTIONS Oxidation-Reduction.

Lecture 223/19/07. Displacement reactions Some metals react with acids to produce salts and H 2 gas Balance the following displacement reaction: Zn (s)

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

Lecture 233/30/05. Redox example: respiration/combustion Balance redox reaction for glucose (C 6 H 12 O 6 ) respiration (same as combustion reaction)

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.

Electrochemistry 18.1 Balancing Oxidation–Reduction Reactions

Zn  Zn2+ + 2e- (oxidation) Cu e-  Cu (reduction)

Chemistry 1011 Slot 51 Chemistry 1011 TOPIC Electrochemistry TEXT REFERENCE Masterton and Hurley Chapter 18.

V. Everything’s Related Positive E° cell means spontaneous. Negative ΔG° means spontaneous. K > 0 means spontaneous. Thus, all of these must be related.

Oxidation-Reduction Reactions REDOX Reactions. Oxidation State Oxidation numbers are very similar to charge. There are some different rules for assigning.

Chapter 26. An electrochemical cell A device that converts chemical energy into electrical energy. A Daniell cell is a device that could supply a useful.

1 Oxidation Reduction Equilibria and Titrations. 2 Oxidation - Reduction reactions (Redox rxns) involve the transfer of electrons from one species of.

Chapter 21: Electrochemistry I Chemical Change and Electrical Work 21.1 Half-Reactions and Electrochemical Cells 21.2 Voltaic Cells: Using Spontaneous.

Chapter 22 REDOX.

Using and Controlling Reactions Assign oxidation numbers and balance atom whose oxidation number changes 2. Balance oxygen by adding water 3. Balance.

Section 10.3—Batteries & Redox Reactions

GALVANIC AND ELECTROLYTIC CELLS

Chapter 21.  Two types: ◦ Voltaic cell: electrons flow spontaneously ◦ Electrolytic cell: electrons are forced to flow.

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

Redox Reactions Year 11 Chemistry ~ Unit 2.

Electrochemistry: Oxidation-Reduction Reactions Zn(s) + Cu +2 (aq)  Zn 2+ (aq) + Cu(s) loss of 2e - gaining to 2e - Zinc is oxidized - it goes up in.

Definitions of Oxidation-Reduction  Loss/Gain of electrons  Increase/Decrease of oxidation number  Determining oxidation numbers.

Balancing Redox Reactions Chem 12. Application of oxidation numbers: Oxidation = an increase in oxidation number Reduction = a decrease in oxidation number.

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

REDOX Part 2 - Electrochemistry Text Ch. 9 and 10.

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.

Oxidation-Reduction Dr. Ron Rusay Fall 2001 © Copyright 2001 R.J. Rusay.

Week 25 © Pearson Education Ltd 2009 This document may have been altered from the original Explain the terms: redox, oxidation number, half-reaction, oxidising.

14 Redox Equilibria 14.1 Redox Equations (Review) 14.2 Electrode Potentials and the Electrochemical Series 14.3 Predicting the Direction of Redox Reactions.

Redox equations.

Electrochemistry Oxidation-Reduction Dr. Ron Rusay Spring 2004 © Copyright 2004 R.J. Rusay.

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

Redox Reactions in Solution. Predicting Redox Rxns (The normal way) 1.Identify all the entities present in the solution 2.Decide which are oxidizing agents.

BATTERIES AND CELLS.

Commercial Voltaic Cells. 3.7…or Applications of Voltaic Cells…

9.2 Electrochemical cells. Two types of electrochemical cells Voltaic cell Spontaneous Chemical  Electrical Uses activity differences between two metals.

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

Balancing Redox Equations – Voltaic (Galvanic) Cells.

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

1 Electrochemistry Chapter 18 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Do Now: What is current? Electric potential or voltage? An Electrode? REDOX? Which reaction below will take place spontaneously? Support your response.

Chapter 20.  Involves the transfer or flow of electrons in a chemical reaction  This flow of electrons results in changes of charges (aka oxidation.

The Daniell cell was invented by John Daniell in 1836.

Topic 19 Oxidation and Reduction. 1)What is the oxidation number of P in PO 4 -3 ? 2)If Cu and Zn and connected, which is the anode? 3)What reaction (oxidation.

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.

Redox reactions. Definitions of oxidation and reduction Oxidation.

Electrochemistry Oxidation-Reduction Dr. Ron Rusay Spring 2004 © Copyright 2004 R.J. Rusay.

Storage cells and fuel cells

10/11/ /11/2018 Energy Changes AQA 2016 Chemistry topic 5.

Electrochemistry- Balancing Redox Equations

January 2018 Electrochemistry Chemistry 30.

Electrochemistry.

Presentation transcript:

Fuel cells Learning objectives: Revise the work covered so far on module 2 of EEE. Explain that a fuel cell uses the energy from the reaction of a fuel with oxygen to create voltage. Explain the changes that take place at each electrode in a hydrogen-oxygen fuel cell. Starter Spend a few minutes looking through the work covered previously on module 2 of EEE (pages 182 – 190).

1.Combine the following two half-equations to form a redox equation: Cu  Cu e - Ag + + e -  Ag 2.Use oxidation states to construct a redox equation for the following reaction: HBr is oxidised to Br 2 by concentrated H 2 SO 4, which is reduced to SO 2 3.Draw a labelled diagram of a simple electrochemical cell made from a copper and a zinc half-cell combined together.

4.Which is the negative electrode? 5.Does oxidation or reduction happen at the negative electrode? 6.What is used as the standard electrode? 7.Draw a labelled diagram of a standard hydrogen electrode.

4.Which is the negative electrode? 5.Does oxidation or reduction happen at the negative electrode? 6.What is used as the standard electrode? 7.Draw a labelled diagram of a standard hydrogen electrode. 8.Why is platinum used as the electrode in this example?

9.Calculate the standard cell potential for the Fe 2+ /Fe and Cr 3+ /Cr cell if: Fe 2+ (aq) + 2e Ý Fe (s)E  = V Cr 3+ (aq) + 3e - Ý Cr (s)E  = V 10.Determine the overall cell reaction. 11.What are the limitations of predicting whether a reaction will occur based on electrode potentials? 12.State an everyday use of electrochemical cells.

A fuel cell uses energy from the reaction of a fuel with oxygen to create a voltage. They operate continuously (assuming fuel is continuously added) and do not need to be recharged. They consist of the reactants flowing in, the products flowing out and an electrolyte which stays in the cell. Fuel cells Next lesson we’ll talk about how they’re used and the advantages and disadvantages of fuel cells.

Hydrogen – oxygen fuel cell (alkaline) Write an equation showing the overall reaction. H 2 + ½O 2  H 2 O These fuel cells can contain either acidic or alkaline electrolytes. Your exam is more likely to focus on the alkaline one (OH - ions). Which reactant is reacting with the OH - ions? It will be the one undergoing oxidation as this is the only way to construct a balanced half-equation (think about the charges involved)? H 2 + 2OH -  2H 2 O + 2e - Negative terminal The other reactant must be forming the OH - ions (as the electrolyte is effectively acting as a catalyst – it is not used up). ½O 2 + H 2 O + 2e -  2OH - Positive terminal

Hydrogen – oxygen fuel cell (alkaline) H 2 + ½O 2  H 2 O H 2 + 2OH -  2H 2 O + 2e - Negative terminal ½O 2 + H 2 O + 2e -  2OH - Positive terminal Check that the two half-equations add together to give the overall equation. If the standard electrode potentials are as follows, calculate E cell 2H 2 O + 2e -  H 2 + 2OH V ½O 2 + H 2 O + 2e -  2OH V E cell = = V

Hydrogen – oxygen fuel cell (acidic) H 2 + ½O 2  H 2 O Now lets try the same for an acidic electrolyte. Acid = H + ions. Which of the reactants will react with H + ions? ½O 2 + 2H + + 2e -  H 2 O Positive terminal Which of the reactants will form H + ions? H 2  2H + + 2e - Negative terminal

Hydrogen – oxygen fuel cell (acidic) H 2 + ½O 2  H 2 O ½O 2 + 2H + + 2e -  H 2 O Positive terminal H 2  2H + + 2e - Negative terminal Check that the two half-equations add together to give the overall equation. If the standard electrode potentials are as follows, calculate E cell 2H + + 2e -  H V ½O 2 + 2H + + 2e -  H 2 O V E cell = 1.23 – 0.00 = V

Hydrogen – oxygen fuel cell (acidic) porous titanium/ platinum cathode to catalyse the ionisation of H 2 porous titanium/ platinum anode to catalyse the reaction of O 2 e–e– e–e– e–e– e–e– e–e– e–e– e–e– e – Acidic membrane allows H + ions to flow through it H H H H H+H+ H+H+ H+H+ H+H+ O O H O H H O H

Methanol fuel cell (acidic) Write the equation for the combustion of methanol. CH 3 OH + 1½O 2  CO 2 + 2H 2 O Assuming we have an acidic electrolyte. Acid = H + ions. Which of the reactants can form H + ions? CH 3 OH + H 2 O  CO 2 + 6H + + 6e - Negative Which of the reactants will react with H + ions? 1½O 2 + 6H + + 6e -  3H 2 O Positive Check that the two half-equations combine to give the overall equation.

Ethanol fuel cell (acidic) Write the equation for the combustion of ethanol. C 2 H 5 OH + 3O 2  2CO 2 + 3H 2 O Assuming we have an acidic electrolyte. Acid = H + ions. Which of the reactants can form H + ions? C 2 H 5 OH + 3H 2 O  2CO H e - Negative Which of the reactants will react with H + ions? 3O H e -  6H 2 O Positive Check that the two half-equations combine to give the overall equation.