Chapter 17

Chapter 17 Corrosion and Degradation of Materials

Introduction • Deterioration of a material due to chemical attack by the environment • Typically, a non-stress related failure • There are exceptions • Terminology • Metals: • Corrosion • Dissolution in the surrounding medium • Primarily an electrochemical phenomenon • Oxidation – formation of oxides • A chemical reaction • Ceramics: Chemical reaction • Corrosion • Oxidation of non-oxide ceramics • Polymers: • Degradation • Chemical reaction with solvents • Decomposition due to UV radiation

An electrochemical process, namely a chemical reaction that also involves the transport of electrons Dissolution of Zn in HCl is an electrochemical process Zn + 2HCl  ZnCl2 + H2 Takes place in two stages Zn  Zn2+ + 2e- Oxidation half reaction at anode 2H+ + 2e-  H2  Reduction half reaction at cathode Electrons that are released in the first reaction may travel through the metal and the second reaction may take place at a different location Both oxidation and reduction reaction are necessary for corrosion to occur Anode: location at which electrons are produced Cathode: location at which electrons are consumed Corrosion of Metals

Oxidation and Reduction Reactions • The oxidation reaction at the anode is typically M1 M1n+ + ne- • The reduction reaction depends upon the environment • When H+ ions are present 2H+ + 2e-  H2 • When O2 and H+ ions are present O2 + 4H+ + 4e-  2H2O • When O2 and H2O are present O2 + 2H2O + 4e-  4(OH-) • In the presence of metal ions M2n+ + e-  M2(n-1)+

Electrochemical Cells • An electrochemical half cell is typically a metal in contact with an electrically conductive liquid, typically a solution containing its ions • Two half cells make up an electro chemical cell • Depending on the metals, oxidation will occur in one cell and reduction in the other The membrane keeps the solutions separated from each other, but is permeable to ions anode cathode anode cathode Zn  Zn2+ + 2e- Fe  Fe2+ + 2e- Cu2+ + 2e-  Cu Fe2+ + 2e-  Fe

Electrochemical Cells • If the two electrodes (anode and cathode) are connected externally with a wire, electrons will flow from the anode to the cathode through the wire • An ammeter (low resistance) will measure a current • A volt meter (high resistance) will measure a potential difference between the two cells • This potential difference depends upon the two half cells

The standard Hydrogen half cell platinum electrode 1.0M solution of H+ ions Hydrogen gas is bubbled at a pressure of 1 atmosphere This cell can be compared with other combinations of metals in contact with their ions, or in general any oxidation or reduction reaction that involves the transfer of electrons A standard half cell consists of a metal in contact with a 1.0M solution of its ions When compared with other half cells, the standard hydrogen half cell may be anodic (H2 forms H+ ions) or cathodic (H+ ions combine with e- to form H2) Electrons will either flow to or from the platinum electrode Other half cells will either be positive or negative with respect to the standard hydrogen half cell Standard emf Series 1.0M 1mol of ions dissolved in 1 liter (1000 cm3) of water

The salt bridge provides a conduit for ions to flow from one solution to the other In this figure, the salt bridge is made up of KCl. Cl- and K+ ions flow through the bridge in opposite directions carrying negative and positive charge, respectively Standard emf Series

Standard emf Series

Standard emf Series • All reactions are shown as reduction reactions • To form an electrochemical cell, an oxidation and a reduction reaction are required • The oxidation reaction will have a potential equal to the negative of the V0 shown • For a reduction reaction (at the cathode) Mn+ + e-  M(n-1)+ V0 • For the oxidation reaction (at the anode) M(n-1)+  Mn+ + e- -V0

Electrochemical Cells • If any two half cells are combined to form an electrochemical cell • The half cell with the more positive V0 will be the cathode • Reduction occurs at this electrode • The half cell with the more negative V0 will be the anode • Oxidation occurs at this electrode • The potential difference that is measured between the two electrodes is ∆V = V0cathode– V0anode

The cell shows a Zn electrode in a 1M solution of ZnSO4 and a Cu electrode in a 1M solution of CuSO4 During the electrochemical reaction Zn goes into solution in the Zn half cell Cu gets deposited on the electrode in the Cu half cell Electrons flow from the anode (Zn) to the cathode through the wire connecting the two electrodes Within the cell, SO42- ions flow through the permeable membrane Over a period of time, the concentration of Zn in the Zn half-cell will increase while the concentration of Cu in the Cu half-cell will decrease. This will change the potential measured from the standard -1.10V Electrochemical (Galvanic) Cells

Cell Potentials • Under standard conditions (oxidation) M1 M1n+ + ne- -V10 (reduction) M2n+ + ne-  M2V20 • Overall cell potential ∆V = V20 -V10 • Under non-standard conditions, electrode potentials may be different • Concentration of ions different from 1M • Temperature different from room temperature • Nernst Equation

Nernst Equation • [M1n+] and [M2n+] are the concentrations of the two ions • n is the number of electrons involved in the reaction • Faraday’s constant F is the charge on 1 mole of electrons F = (6.023x1023 electrons/mol) x (1.602x10-19C/electron) = 96,500 C/mol • R is the universal gas constant • T is temperature in (K)

Corrosion of single electrode • Single metal electrodes corrode under certain circumstances due to microscopic galvanic cells that are set up when the metal is in contact with the electrolyte • Examples • Zn in contact with HCl • Zn  Zn2+ + 2e- • 2H+ + 2e-  H2  • Overall reaction • Zn + 2HCl  ZnCl2 + H2

Corrosion of single electrode • Rusting of Fe in oxygenated water • Rust is ferric hydroxide Fe(OH)3 • At the local anode • Fe  Fe2+ + 2e- • At the local cathode • O2 + 2H2O + 4e-  4(OH-) • Overall reaction • 2Fe + O2 + 2H2O  2Fe(OH)2  • In the presence of additional O2 • 2Fe(OH)2 + H2O + ½ O2  2Fe(OH)3 (rust)

Examples of Galvanic cells • Identify anodic and cathodic reactions and determine if corrosion will occur • Cu and Zn immersed in dilute solution of CuSO4 • Anode: • Cathode: • Cell potential • Cu in oxygenated water • Anode: • Cathode: • Cell potential:

Examples of Galvanic cells • Mg and Fe connected by an external wire and immersed in 1% NaCl solution • Anode: • Cathode: • Cell potential:

Ion Concentration Galvanic Cell • Fe electrodes in contact with solutions with different concentrations of Fe2+ ions • In both cells, if the anodic reaction occurs, Fe will go into solution Fe  Fe2+ + 2e- • Use Nernst equation to calculate cell potentials 0.001M Fe2+ 0.01M Fe2+

Oxygen Concentration Galvanic Cell • Differences in oxygen concentration can set up galvanic cells Fe  Fe2+ + 2e- 0.440V O2 + 2H2O + 4e-  4(OH-) -0.401V ∆V = 0.039V • Fe will go into solution in the low oxygen content solution • Application • If an iron rod is left immersed in water, corrosion occurs not a the surface (high oxygen) but below the surface (low oxygen) High O2conc. Low O2 conc.

Chapter 17

Chapter 17

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Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

CHAPTER 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

Chapter 17

CHAPTER 17

CHAPTER 17

Chapter 17