Wet Corrosion

Kivonat:

Two clear and distinct types of corrosion include dry corrosion i.e. corrosive action without the presence of moisture and wet corrosion, involving the transfer of electrons during oxidation and reduction.

Corrosion is defined as the deterioration of a material by chemical or electro chemical reactions with its environment. Due to corrosion the useful properties of a metal like malleability, ductility, electrical conductivity and also the surface appearance are compromised. The most familiar example of corrosion is the rusting of iron when exposed to atmospheric conditions.

There are several types of corrosion, including wet corrosion and dry corrosion.

Dry corrosion occurs when there is no water or moisture to aid the corrosive process, and the metal oxidizes with the atmosphere alone. Wet corrosion of metals occurs through electron transfer, involving two processes, oxidation and reduction. In oxidation, the metal atoms lose electrons. The surrounding environment then gains the electrons in reduction. The metal, where electrons are lost, is called the anode. The other metal, liquid or gas which gains the electrons is called the cathode.

Air contains, on average, 21% oxygen, 78% nitrogen, and 1% argon. It can also contain water vapour, ozone, and carbon dioxide.

Water is very commonly aerated which again means there is oxygen available for reaction with metals.

There are many factors that dictate how corrosive an environment is. One is the amount of oxygen available to form corrosion products or the presence of water or moisture which greatly accelerate the rate of corrosion. Another is the presence of other elements, ions and compounds that can limit or enhance corrosion rates. Therefore corrosion rates are often considered in different atmospheres: industrial, rural and marine. Each of these environments will contain different amounts of oxygen and other “pollutants” like ozone, salt, dusts, sulphur dioxide, ammonia, hydrogen and hydrogen sulphide.



Figure 1: Types of corrosion

Electrochemical theory of wet corrosion: fundamentals

As with dry corrosion wet corrosion reactions are only possible if the free energy of the products of reaction is lower than the free energy of the reactants. This is the case however for the reaction of nearly all metals with water and oxygen to give metal hydroxides:

M + H2O (l) → M(OH)2 (s) … (1)

This enables reaction 1 above to proceed through the coupling of two primary corrosion reactions:

A: M→M2+ + 2e … (2)
(Anode reaction: destroys metal, releases electrons, oxidation)

C: 2e + H2O + ½O2 → _2OH … (3)
(Cathode reaction: consumes electrons; electron sink reaction: reduction).

Electrons liberated in the anode reaction A flow to the site of the cathode reaction C through the conducting metal. The movement of dissociated ions carries an equal ionic current in the water. The distances over which these currents flow can vary from microns to many metres. All wet corrosion processes can be analysed in terms of anodic and cathodic reactions.

The anodic process is the direct cause of damage to metallic structures but both an anodic and a cathodic process must occur for a corrosion cell to be formed. The corrosion of metals by reaction with air and water to form metal hydroxides as shown above is a very important wet corrosion process, especially in the construction industries. There are other corrosion reactions resulting from, for example, other cathode reactions (electron-consuming).

The rate of wet corrosion may often be very high compared with dry corrosion on the same metal at the same temperature. There are two underlying reasons for this:
- the dipolar water molecule stabilizes the free (dissociated) metal ions in solution
- the metallic structure and water in contact with it can both conduct electric current

This enables reaction 1 above to proceed through the coupling of two primary corrosion reactions:

All wet corrosion processes can be analysed in terms of anodic and cathodic reactions.

The anodic process is the direct cause of damage to metallic structures but both an anodic and a cathodic process must occur for a corrosion cell to be formed

The corrosion of metals by reaction with air and water to form metal hydroxides as shown above is a very important wet corrosion process, especially in the construction industries. There are other corrosion reactions resulting from, for example, other cathode reactions (electron-consuming)

2e + 2H+ → H2 … (4)

2e + M2+ → M2+ … (5)

or other anode reactions (electron releasing)

M + H2O →MO + 2H+ 2e … (6)

When a metal M is placed in pure water, some ions will immediately pass into solution:

M→M2+ + 2e … (7)

The build-up of negative charge on the metal and the build-up of metal ions in solution makes possible a back-reaction:
M←M2+ + 2e‾ … (8)

and ultimately an equilibrium is established:

M↔_M2+ + 2e … (9)

At this stage, a steady potential difference now exists between metal and solution. The magnitude of this potential difference depends on the metal and composition of the solution. It is not possible to measure this potential difference for a single metal, but the potential difference (emf) between two metals dipping into a solution can be measured. Under well-defined conditions, this enables a single potential Em (relative to a common reference) to be assigned to every metal.



Figure 2: Wet corrosion

Keresés a Tudástárban

Adja meg a keresendő kifejezést:

Keresés a következő szerint

Teljes szöveg
Kulcsszavak

Cím
Kivonatok

The Total Materia database contains many corrosion resistant materials across a large range of countries and standards.

Where available, full property information can be viewed for materials including chemical composition, mechanical properties, physical properties, advanced property data and much more.

Using the Advanced Search page, it is possible to search for materials by their key descriptive words detailed in the standard title by using the Standard Description function of Advanced Search.

It maybe that you need to further narrow the search criteria by using the other fields in the Advanced Search page e.g. Country/Standard.

Then click Submit.

solution img

A list of materials will then be generated for you to choose from.

solution img

After clicking a material from the resulting list, a list of subgroups derived from standard specifications appears.

From here it is possible to view specific property data for the selected material and also to view similar and equivalent materials in our powerful cross reference tables.

solution img

For example, by clicking on the chemical composition link on the subgroup page it is possible to view chemical composition data for the material.

solution img

For you’re a chance to take a test drive of the Total Materia database, we invite you to join a community of over 150,000 registered users through the Total Materia Free Demo.