Electrolysis

Educational level: this is a secondary education resource.

Electrolysis is the very first electrochemical technique ever used. The word is derived from the Greek words "electron" and "lysis" the first in its present day meaning refering to electricity, the second to decomposition, so: decomposition by the means of an electricity.

Example edit

a Daniell cell consists of a zinc anode (an electron collector), is oxidized as it dissolves into a zinc sulfate solution, the dissolving zinc leaving behind its electrons in the electrode according to the oxidation reaction (s = solid electrode; aq = aqueous solution):

\mathrm {Zn_{(s)}\rightarrow Zn_{(aq)}^{2+}+2e^{-}\ }

The zinc sulfate is the electrolyte in that half cell. It is a solution which contains zinc cations $\mathrm {Zn} _{}^{2+}$ , and sulfate anions $\mathrm {SO} _{4}^{2-}\$ with charges that balance to zero.

In the other half cell, the copper cations in a copper sulfate electrolyte are drawn to the copper cathode to which they attach themselves as they adopt electrons from the copper electrode by the reduction reaction:

\mathrm {Cu_{(aq)}^{2+}+2e^{-}\rightarrow Cu_{(s)}\ }

Prerequisites edit

A basic understanding of the following topics is assumed:

Atom
Reduction and oxidation or redox reaction
Electrical potential

Short History edit

Electrolysis dates back to the turn of the 18^th into the 19^th century. At that time Sir Humphry Davy applied the then newly discovered voltaic pile to molten potassium hydroxide, releasing the metal out of its compound. Although the source of the electrical current has changed over time, principals have not.

Principals edit

At its base during electrolysis a redox reaction is performed. The difference between the plain redox reaction between two chemical compounds and electrolysis is found in the route an electron uses to move from one atom to another. In ordinairy redox reactions the electron is directly transferred between the atoms. In electrolysis the electrons travel along the electrical circuitry.

Techniques edit

The basic apparatus used in electrolysis is shown on the right. It conists of a voltage source, leads, two electrodes and a container with the substance to be electrolysed, in this case: a beaker glass with water. The beaker glass with its content is referred to as: electrochemical cel^[1]. The part of the leads immerged in the solution are called "electrodes". In the electrolysis of water these electrodes are made of platinum. The voltage source in general is adjusted to a few volts.

The names of the electrodes are:

Anode, the electrode at which the oxidation reaction takes place.
Cathode, the electrode at which the reduction reaction occurs.

The naming of the two electrodes does not depend on the use of the electrochemical cell.

Reactions edit

The reactions taking place are treated separately, as they are spatially separated too.

Anodic Or Oxidation Reaction edit

At the anode an oxidation reaction is taking place. The anode is made positive by its connection to the positive terminal of the voltage source. It has a great oxidizing power. Electrons do "want" to go there. As in this example water is the only component in the cell, it is to be oxidized according to:

2 H₂O O₂ + 4 H⁺ + 4 e⁻ ^[2]

The formed oxygen ascends as bubbles and might be caught in a test tube and tested for, otherwise it escapes into the air. The ions of hydrogen simply dissolve in the remaining water. The electrons are taken in by the anode.

The anode, however, is connected to the positive terminal of the voltage source. The drop in potential due to the arrival of the electrons on the anode leads to the transfer of these electrons to the negative terminal: the potential of the anode does not change.

Cathodic Or Reduction Reaction edit

At the cathode a reduction reaction is taking place. The cathode is very rich in electrons, as it is connected to the negative terminal of the voltage source. It has a great reducing power. As in this example water is the only component in the cell, it is to be reduced according to:

2 H₂O + 2 e⁻ H₂ + 2 OH⁻

The formed hydrogen ascends as bubbles and might be caught in a test tube and tested for, otherwise it escapes into the air. The ions of hydroxide simply dissolve in the remaining water and of course will react with the hydrogen ions formed at the anode. The electrons are taken in by the anode.

The anode, however, is connected to the positive terminal of the voltage source. The drop in potential due to the arrival of the electrons on the anode leads to the transfer of these electrons to the negative terminal: the potential of the anode does not change.

Complete Reaction edit

As is seen in the reaction equations, hydrogen and oxygen are formed. Although the equations are balanced in themselves, the over all reaction needs some adjustment, as four electrons are taken in at the anode, and only two are released at the cathode. To balance the over all reaction, the cathodic one should be read twice, so:

2 H₂O 2 H₂ + O₂

More Complex Electrolysis edit

Picture of a zinc iodide containg electrochemical cell. The text is german:
Lösung = solution
Graphit=Carbon

The example of water being electrolysed is straight forward. A more complicated situation arises when a solute is added. Now at both electrodes several reactions might be possible, but only one will proceed. As an example a solution of zinc iodide is used. To predict the reactions at each electrode that will occur the following procedure will help:

Determine the components present at the anode. The components and their respective redox potentials for oxydation are:

Component	E^o	For carbon no value is found, as carbon is an inert electrode material, it simply does not react. For Zn²⁺ no value is found because of the impossibility to oxidize this ion At the anode an oxidation will take place. The strongest reductor will deliver the electrons. Inspection of the table of Standard Electrode Potentials leads to the numbers in the second row of the table. By far, iodide is the stronger reductor (has the lower E^o) so iodide will be oxydized to Iodine.
C^o	?
H₂O	+1.23
Zn²⁺	−
I⁻	+0.53

Determine the components present at the cathode. The components and their respective redox potentials for reduction are:

Component	E^o	Again, for carbon no value is found, as carbon is an inert electrode material, it simply does not react. But now for iodide too no value is found as it is not possible to reduce the iodide further. At the cathode a reduction will take place. The strongest oxydator will accept the electrons. Inspection of the table of Standard Electrode Potentials leads to the numbers in the second row of the table, which then leads to the conclusion that the Zn²⁺ ion will accept the electrons and be converted to its metallic state.
C^o	?
H₂O	−0.8277
Zn²⁺	−0.7618
I⁻	−

Reference edit

Wikipedia:Electrochemical cell

↑ Electrochemical cells are discussed more extensively in the text on potentiometry.
↑ To balance the equation explicitly the charge of the electrons is written here.

[1] Electrochemical cells are discussed more extensively in the text on potentiometry.

[2] To balance the equation explicitly the charge of the electrons is written here.

[1]

[2]