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Introduction to Corrosion Science and Engineering
Rating: 4.6 out of 5(72 ratings)
231 students

Introduction to Corrosion Science and Engineering

Understanding Corrosion Mechanisms and Corrosion Mitigation Measures
Created byCorroZone Ltd.
Last updated 12/2024
English

What you'll learn

  • Understand the key differences between high temperature and aqueous corrosion, and classify corrosion based on mechanism and form.
  • Understand the electrochemical nature of aqueous corrosion, including anodic and cathodic reactions and their influence on local pH.
  • Comprehend essentials of electrical charge movement in metals and solutions.
  • Understand and apply Faraday's law to convert electrical current into reaction rates.
  • Represent corroding surfaces in terms of electrical currents.
  • Gain practical understanding of measuring potential differences, significance of reference electrodes.
  • Understand the Nernst equation to determine equilibrium potentials, construct Pourbaix diagrams, and analyze the thermodynamic implications.
  • Understand Evans diagrams and Tafel law, and their application in calculating corrosion current and representing behavior of corroding electrodes.
  • Gain insight into diffusion-limited reactions, particularly oxygen reduction reaction and its significance in metal corrosion.
  • Understand the mechanism of uniform corrosion, influencing factors, and mitigation strategies.
  • Understand galvanic corrosion, its mechanisms, factors influencing severity, and mitigation measures.
  • Understand crevice corrosion, mechanisms, initiation process, factors influencing severity, and preventive measures.
  • Understand pitting corrosion mechanism, factors influencing severity, and evaluate material performance against pitting.
  • Understand the fundamental principle of cathodic protection as a corrosion prevention method, including sacrificial anodes and impressed current systems.
  • Understand the fundamental principle of cathodic protection as a corrosion prevention method, including sacrificial anodes and impressed current systems.
  • Understand the significance of organic coatings in surface protection, the paint key ingredients and their function, and the protective mechanism.
  • Acquire knowledge of mechanisms contributing to the failure of organic coatings and the subsequent corrosion of the metal substrate.
  • Understand metallic and non-metallic inorganic coatings, their categories, protective mechanisms, and methods of obtaining them.

Course content

4 sections24 lectures5h 15m total length
  • Introduction to Section 10:56
  • Why corrosion occurs?5:15

    By the end of this lecture, learners should acquire an understanding of why metal corrosion occurs, and of the key differences between high temperature corrosion and aqueous corrosion. The lecture explains the classification of corrosion based on mechanism and form, distinguishing between uniform and localized corrosion. Additionally, learners will gain insights into specific localized corrosion types, such as galvanic corrosion, crevice corrosion, pitting corrosion, intergranular corrosion, and flow-affected corrosion.

  • Types of localised corrosion7:38
  • Electrochemical nature of aqueous corrosion.7:16

    By the end of this lecture, learners should grasp the electrochemical nature of aqueous corrosion, understanding key processes like anodic and cathodic reactions, charge movement in the metal and solution, and the necessity of maintaining charge neutrality. Learners will comprehend the simultaneous occurrence of oxidation and reduction reactions on a corroding surface, where metal oxidation leads to corrosion. The terms 'anodic' and 'cathodic' reactions will be associated with oxidation and reduction, respectively, emphasizing wet corrosion as an electrochemical process allowing spatial separation of reactions on the metal surface. The lecture emphasizes the balance between anodic and cathodic reactions, with the slower process determining the corrosion rate.

  • Anodic and cathodic reactions.8:00

    By the end of this lecture, learners should comprehend the significance of anodic and cathodic reactions in corrosion and their influence on local pH. Anodic reactions lead to the loss of metallic material, with resulting metal ions having various outcomes, from dissolution to forming protective oxides. Cathodic reactions, including oxygen reduction and hydrogen evolution, impact pH by generating hydroxyl ions and consuming hydrogen ions. This interplay influences localized corrosion, with anodic regions becoming more acidic and cathodic regions more alkaline. The lecture highlights the spatial separation of reactions, creating a pH gradient on the corroding surface.

  • Charge transport in metals and in solutions (electrolytes).8:39

    By the end of this lecture, learners should grasp the essentials of electrical charge movement in metals and solutions. The lecture introduces the concept of electrolytes as solutions capable of conducting electrical charge due to the movement of charged ions. While electrons are responsible for charge moveement within metals, electrolytes rely on the movement of positive and negative ions. The mechanisms differ, requiring electrochemical reactions at the metal-electrolyte interface for charge to traverse the surface. An important implication is that anodic regions serve as sources of positive ions, and cathodic regions as sources of negative ions. This ion movement, exemplified by chloride migration towards anodic regions, plays a role in triggering localized corrosion mechanisms.

  • Section 1 Quiz

Requirements

  • No prior corrosion or electrochemistry experience required. High-school level understanding of chemistry and electrical concepts is sufficient.

Description

This course introduces you to the fundamental principles of aqueous corrosion, to the most common corrosion mechanisms, and to the most common corrosion protection measures.

It is suitable for anyone who would like to learn about corrosion, either as a part of their job, as a part of their research, or as a student that is just getting started in corrosion.

The course is organized in four sections. In the first section, we will consider what happens on a corroding surface, looking at the electrochemical reactions involved, and at the changes induced into the environment. In the second section, we will go briefly through the most important concepts of electrochemistry, that are needed for understanding any corrosion process. In section three, we will discuss the most common corrosion mechanisms (general corrosion, galvanic corrosion, crevice corrosion and pitting), the key factors that affect them, and what can be done to reduce their impact. In section 4, we will discuss the most common corrosion protection measures, such as cathodic protection, paints, corrosion inhibitors, and inorganic coatings.

By the end of this course, you should have an overview of the most common topics that are related to corrosion, and you should be able to start looking independently for specific knowledge to address the particular corrosion problem that you may be facing.

Please note that, due to the nature of the subjects,  there is some unavoidable overlap in the topics discussed in this course and the course 'Learn the Fundamentals of Corrosion Electrochemistry'. If you are looking for a general course about corrosion ( corrosion mechanisms, corrosion protection measures, and minimal electrochemistry theory), this is  the most appropriate course for you. If you are looking for a more in-depth discussion of corrosion electrochemistry, the best course for you is 'Learn the Fundamentals of Corrosion Electrochemistry', available on this platform.

Who this course is for:

  • This course is designed for engineers, researchers or STEM students who would like to gain a broad knowledge on about corrosion, either because it is needed as a part of their job, as a part of their research, or their final university project.